co-delivery of two growth factors from combined plga and ... · from combined plga and plla/pcl...
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I
Co-delivery of Two Growth Factors From Combined PLGA and PLLA/PCL Microsphere Scaffolds for Spinal Cord
Injury Repairs
by
Zhongxuan. Li
Thesis submitted to the
Faculty of Graduate and Postdoctoral Studies
in partial fulfillment of the requirements for the degree of
Master of Applied Science Chemical Engineering
University of Ottawa
Ottawa, Ontario, Canada
©Zhongxuan Li, Ottawa, Canada, 2014
I
Abstract
The purpose of this study is to demonstrate the effectiveness of spheres-in-tube
structured scaffolds to sequentially deliver two biomolecules during two phases of
tissue regeneration following spinal cord injury (SCI). Scaffolds were synthesized of
a poly (lactic-co-glycolic acid) (PLGA) base combined with Poly (L-lactic acid) /
Poly (ε-caprolactone) (PLLA/PCL) microspheres.
The scaffolds are constructed by leveraging the different solubilities of PLGA,
PLLA and PCL in super critical carbon dioxide and ethyl acetate during fabrication
processes. Microspheres can reduce the pore size and porosity of PLGA scaffolds;
this enhances their mechanical strength and enables them to provide long-term
treatment without collapse.
The release of the epidermal growth factor (EGF) and basic fibroblast growth factor
(FGF-b) are being used to study the release profiles of the designed scaffolds. The
analysis shows that FGF-b is released from high porosity PLGA base as the first
delivery vehicle and completes the release in the first week. PLLA or PCL
microspheres, having the property of sustainably delivering encapsulated EGF in 36
days, are used as the second drug delivery vehicle.
FGF-b released within the first week can mimic biomolecules used to protect the
surviving neurons and promote the development of sprout axons. The sustained
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release of EGF from microspheres is used for long-term therapy to differentiate
multipotent cells into determined types at the injury site.
The results demonstrate that these enhanced parameters along with the ability of
sequential co-delivery of growth factors, make these designed scaffolds a promising
candidate in SCI studies.
III
Résumé
L’objectif de cette étude est de démontrer l’efficacité des hyper-structures de type
sphère dans un canal cylindrique pour émettre deux biomolécules de façon
séquentielle pendant deux phases de régénération des tissues suite à un traumatisme
médullaire. Les hyper-structures en question sont fabriquées à base de poly
lactique-co-glycolique d'acide (PLGA) avec des microsphères d’acide
polylactique/polycaprolactone (PLLA/PCL).
La fabrication des hyper-structures se fie sur les différentes solubilités du PLGA,
PLLA, et PCL dans le CO2 supercritique et l’acétate d'éthyle. Les microsphères
peuvent réduire les diamètres des pores et la porosité des hyper-structures de PLGA,
améliorant ainsi leur résistance mécanique pour les traitements à long terme.
Les profils d’émissions des facteurs de croissance épidermique (EGF) ainsi que des
facteurs de croissance des fibroblastes (FGF-b) sont ensuite déterminés dans ces
hyper-structures. L’analyse démontre que, dans un premier temps, le FGF-b est livré
à l’aide du PLGA à haute porosité pendant une période d’une semaine. Par la suite,
les microsphères PLLA ou PCL servent de véhicules de livraison. Ces microsphères
ont la propriété d’émettre les EGF encapsulés de façon continue sur une période de
36 jours.
Les FGF-b émis dans la première semaine peuvent imiter les biomolécules qui
protègent les neurones survivants ainsi que stimuler la croissance de nouveaux
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bourgeons axonaux. Pour le traitement à long terme, l’émission continue d’EGF à
l’aide des microsphères sert à différentier les cellules multipotentes.
Les résultats démontrent que les améliorations dans la fabrication des
hyper-structures couplée avec la livraison séquentielle des facteurs de croissance
offrent un mécanisme prometteur dans le traitement des traumatismes médullaires.
V
Acknowledgements
I take great pleasure in thanking the many people who have helped me in my
studies at the University of Ottawa. First and foremost, I would like to express my
sincere appreciation and deep thanks to my supervisor, Dr. Xudong Cao, for giving
me the opportunity to complete a master’s degree in chemical engineering under his
guidance. His encouragement and advice greatly helped me in both my research and
in writing this thesis.
I also would like to thank Donald McLachlan, Patrick Assouad, and Dr.
Thibault for their assistance with my thesis writing. I would like also to thank the
help form my research group throughout my research project.
Last but not the lease, I would like to extend my thanks to my parents Min Li,
Ru Zhang, and my grandfather Bifa Zhang, whose encouragement have always
sustained me.
VI
Contents
Abstract ........................................................................................................ I
Résumé ...................................................................................................... III
Acknowledgements .................................................................................... V
List of Figures ............................................................................................ X
List of Tables ............................................................................................ XII
Abbreviation ........................................................................................... XIII
Chapter 1 Introduction ................................................................................ 1
1.1 Spinal cord injury ...................................................................... 1
1.2 Time-line for SCI treatment ....................................................... 5
1.3 Scaffold design .......................................................................... 7
1.3.1 Introduction of Designed Scaffold .............................................................. 7
1.3.2 Solubility of Material ........................................................................................ 8
1.3.3 Super Critical CO2 Foaming Process .......................................................... 8
1.3.4 Release of Biomolecules ................................................................................. 9
1.4 Research Approach .................................................................... 9
1.5 Research Goals ........................................................................ 10
Chapter2 Literature review ....................................................................... 12
2.1 Cellular Therapy ...................................................................... 12
VII
2.1.1 Different Cell Types Used in Cellular Treatment .............................. 13
2.1.2 Exogenous-‐based Therapies for SCI ....................................................... 16
2.1.3. Endogenous-‐based Therapies for SCI ................................................... 18
2.1.4 Conclusion ......................................................................................................... 19
2.2 Molecular Therapy ................................................................... 20
2.2.1 Protecting the Spinal Cord .......................................................................... 20
2.2.2 Overcoming Inhibitions ............................................................................... 21
2.2.3 Stimulating the Axonal Growth ................................................................ 22
2.2.4 Cell Differentiation ......................................................................................... 25
2.2.5 Conclusion ......................................................................................................... 28
2.3 Delivery of Growth Factors ..................................................... 29
2.3.1 Co-‐deliver Growth Factors at Same Time ............................................ 30
2.3.2 Sequential Delivery of Growth Factors ................................................. 32
2.3.3 Controlled Release ......................................................................................... 41
2.4 Scaffold Delivery Systems ...................................................... 43
2.4.1 Co-‐delivery Systems ...................................................................................... 44
2.4.2 Materials ............................................................................................................. 47
2.4.3 Fabrication Techniques ............................................................................... 54
Chapter 3. Experimental ............................................................................ 57
3.1 Materials .................................................................................. 57
3.2 Scaffold Preparation ................................................................ 58
VIII
3.2.1 Microsphere ...................................................................................................... 58
3.2.2 Scaffold Tube .................................................................................................... 60
3.3 In Vitro Release ....................................................................... 62
3.3.1 BSA Release ....................................................................................................... 63
3.3.2 Growth Factor Release ................................................................................. 68
3.4 Characterization of Scaffold .................................................... 70
3.4.1 Scanning Electron Microscopy .................................................................. 70
3.4.2 Degradation Study .......................................................................................... 71
3.4.3 Mechanical Testing ........................................................................................ 74
Chapter 4 Results and Discussions ........................................................... 76
4.1 Release Study ........................................................................... 76
4.1.1 BSA Release Studies ....................................................................................... 76
4.1.2 Growth Factors Release Studies ............................................................... 80
4.1.3 Sequential Release Approach .................................................................... 82
4.1.4 BSA Release Versus Growth Factors Release ..................................... 85
4.1.5 Encapsulation Efficiency in Growth Factor Release ........................ 85
4.2 Scanning Electron Microscopy ................................................ 86
4.3 In Vitro Degradation Study ..................................................... 90
4.3.1 Mass Loss ........................................................................................................... 90
4.3.2 SEM Image Analysis ....................................................................................... 92
4.3.3 Structure Change in Mass Loss Studies ................................................. 96
IX
4.4 Compressive Test ..................................................................... 97
4.4.1Mechanical Properties of Scaffolds .......................................................... 99
4.4.2 Structure Change in Mechanical Testing ........................................... 101
4.4.3 Degradation in Mechanical Testing ..................................................... 102
4.5 Compare Between Scaffolds .................................................. 103
4.6 Conclusions ............................................................................ 104
Chapter 5 Suggestions for Future Work .................................................. 106
5.1 Materials ................................................................................ 106
5.2 Microsphere Fabrication Process ........................................... 107
5.3 Micro-architecture ................................................................. 108
5.4 Inner Structure of the Scaffold .............................................. 109
Attachment .............................................................................................. 111
Bibliography ............................................................................................ 114
X
List of Figures
Figure 1 Green ribbon for Spinal Cord Injury ...................................................................... 2
Figure 2 Spinal cord injury degeneration process ............................................................. 4
Figure 3 Approaching regeneration process ........................................................................ 5
Figure 4 Structure of designed scaffold and distribution of drug location. ............ 7
Figure 5 Scheme of two molecules sequentially release from multifunctional
particles as drug carrier ................................................................................................... 35
Figure 6 Scheme of two molecules sequentially release from polymer well as
a drug carrier ......................................................................................................................... 36
Figure 7 Scheme of two molecules sequentially release from coating based
two-‐dimensional drug carrier ........................................................................................ 38
Figure 8 Scheme of two molecules sequentially release from particles in gel
structured three-‐dimensional drug carrier ............................................................. 40
Figure 9 Structure of Poly (lactic acid-‐co-‐glycolic acid)(PLGA) ................................ 51
Figure 10 Structures of Poly (L-‐lactic acid)(PLLA) and Poly (DL-‐lactic
acid)(PLLA) ............................................................................................................................ 52
Figure 11 structure of Poly (ε-‐caprolactone)(PCL) ........................................................ 53
Figure 12 Dip-‐coating synthesized process ....................................................................... 61
Figure 13 In vitro release studies of BSA release from PCL (MS)-‐PLGA (base)
scaffold in 42 days. .............................................................................................................. 78
XI
Figure 14 In vitro release studies of BSA release from PLLA (MS)-‐PLGA (base)
scaffold in 42 days. .............................................................................................................. 79
Figure 15 In vitro release studies of EGF and FGF-‐b from PCL (MS)-‐PLGA
scaffold in36 days. ............................................................................................................... 81
Figure 16 In vitro release studies of EGF and FGF-‐b from PLLA (MS)-‐PLGA
scaffold in 36 days. .............................................................................................................. 82
Figure 17 SEM images of PLGA in A, B; PLLA (MS)-‐PLGA in C, D ; PCL
(MS)-‐PLGA in E, F ; different magnifications A, C, E with a scale bar of
300 μm and B, D, E with a scale bar of 80 μm ......................................................... 89
Figure 18 Percentage of mass loss for in vitro degradation study of PLGA,
PLLA (MS)-‐PLGA, and PCL (MS)-‐PLGA scaffolds in 6 weeks. ........................... 91
Figure 19 SEM images of PLGA scaffolds in week 1 a, 3 b, 5 c; PLLA
(MS)-‐PLGA scaffolds in week 1 d, 3 e, 5 f ; PCL (MS)-‐PLGA scaffolds in
week 1 g, 3 h, 5 i. All images are under the same magnification with a
scale bar of 80 μm ............................................................................................................... 95
Figure 20 Young’s Modulus for PLGA, PLLA (MS)-‐PLGA, PCL (MS)-‐PLGA
scaffolds over time. ............................................................................................................. 99
Figure 21 Compression stress-‐strain curve of PLGA scaffold. ................................ 100
Figure 22 Non-‐ideal and ideal molecule distributions in microsphere .............. 108
Figure 23 Section view structure of improved scaffold ............................................. 110
XII
List of Tables
Table 1 Sustainable release from double-‐wall microsphere ...................................... 43
Table 2 Advantages and disadvantages of using different biodegradable
materials .................................................................................................................................. 51
Table 3 Advantages and disadvantages for various scaffold syntheses
methods ................................................................................................................................... 56
Table 4 Components in each group of scaffold in BSA release test ......................... 65
Table 5 Components of each scaffold in growth factors release test ...................... 69
Table 6 Components of each group of samples used by SEM and compressive
test .............................................................................................................................................. 70
Table 7 Components of each group of samples used in mass loss study .............. 73
XIII
Abbreviation
ANG-1 Angiopoietin-1
AP Alkaline phosphatase
BDNF Brain-delivered neurotrophic factor
BMP Bone morphogenetic protein
BMSC Bone marrow stromal stem cell
BSA Bovine serum albumin
CAD Computer-aided design
CAM Computer-aided manufacturing
ChABC Chondroitinase ABC
CNS Central nervous system
CpG C phosphate G
CS Chitosan
CSPG Chondroitin sulfate proteoglycan
CyA Cyclosporin A
DCM Dichloromethane
XIV
Dox Doxorubicin
Dtxl Decetaxel
ECMS Extracellular matrices
ECT Encapsulation cell technology
EDK Elisa development kit
EGF Epidermal growth factor
ELISA Enzyme-linked immunosorbent assay
EPO Erythropoietin
ES Embryonic stem cells
FGF Fibroblast growth factor
FGF-2 Fibroblast growth factor-2
FGF-b Fibroblast growth factor-basic
FGF-b Fibroblast growth factor-basic
GDNF Glial cell line-derived neurotrophic factor
GF Growth factor
HAEC Human aortic endothelial cell
HGF Hepatocyte growth factor
XV
IGF-1 Insulin-like growth factor-1
IL-10 Interleukin-10
K-wires Kirschner wires
MAG Myelin-associated glycoprotein
MS Microsphere
NGF Nerve growth factor
NP Neural progenitor cell
NSPC Neural stem cell/ Progenitor cell
NT-3 Neurotrophin-3
OEC Olfactory ensheathing cell
PCL Poly (ε-caprolactone)
PDGF Platelet-derived growth factor
PDLA Poly (D-lactide)
PDLLA Poly (DL-lactide)
PGA Poly (glycolic acid)
PHEMA Poly (2-hydroxyethyl methacrylate)
PLGA Poly (lactic acid-co-glycolic acid)
XVI
PLLA Poly (L-lactic acid)
PNS Peripheral nervous system
POE Poly (orthoester)
PPF Precision particle fabrication
PVA Poly vinyl alcohol
PVC Poly vinyl chloride
RA Retinoic acid
RNAi Ribonucleic acid
SC Schwann cell
SCI Spinal cord injury
SEM Scanning electron microscopy
Shh Sonic hedgehog
TGF-β Transforming growth factor-β
TMC Trimethylene carbonate
TNT Titania nanotube
1
Chapter 1 Introduction
1.1 Spinal cord injury
The human nervous system consists of two regions, the central nervous system
(CNS) and the peripheral nervous system (PNS). The CNS, which consists of the brain
and the spinal cord, integrates information from the PNS, processes and then guides the
activity. In the spinal cord the CNS is made up of two parts, grey matter in a
butterfly-shaped core consisting of neuronal cell bodies, surrounded by white matter
containing the long axons. The spinal cord is encased in the bony vertebral column and
is attached to the brain stem conveying information from the skin, joints, and muscles
of the body to the brain via spinal nerves.
Spinal cord injury (SCI) is caused instantly by physical impact trauma or gradually
by illness such as tumors or infection. Function loss on the motor and sensory pathways,
are typically associated with two types of spinal cord injuries, complete spinal cord
injury (of both the motor and the sensory pathways) and incomplete spinal cord injury
(partial random preservation of the motor or the sensory pathway).
According to a worldwide literature survey, 223-755 per million people spent their
life in wheelchairs due to medical comorbidity [1]. The latest data provided on Spinal
Cord Injury Awareness estimates 275000 people in the US and 86000 people in Canada
2
are living with spinal cord injury. In Canada approximately 4300 people are paralyzed
every year due to SCI, resulting in an overall estimated cost to the health care system of
$3.6 billion [2]. Road traffic accidents, domestic and work-related accidents, sports
injuries and acts of violence are the top reasons for traumatic injury. Bacterial and viral
infections to spinal nerve cells and pressure from the growth of cysts or tumors
blocking blood supply are the main reasons that cause SCI without trauma. In SCI, over
50% of the cases happened to people under 30 years old, with over a 4:1 male to female
ratio [2]. SCIs often require lifelong high cost treatment and therefor are a big concern
to society. The green ribbons (shown in Figure 1), symbols for SCI, are customized to
various gifts in Zazzle Canada’s unique collection, expressing people’s expectations for
research to find a cure for patients [3].
Figure 1 Green ribbon for Spinal Cord Injury
Pathophysiology of injury has been studied for decades; however, full
understanding of spinal cord injuries is still a long way off. It is believed that the CNS
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has the potential of self-reparation after injury due to spontaneous regenerative events.
Axons could sprout and persist after the injury, but with limited cellular, molecular
mechanisms and other reasons, the capacity for regeneration is still limited [4].
After initial trauma displaced fragments of bone, lost tissue, damaged vessels,
axons and neurons at the injured site can disrupt long tract neural connections [5]. Then
the damage site on the injured spinal cord may rapidly swell within minutes (caused by
immune responses) thereby affecting the nerve pathways. During the post-traumatic
stage, built up amino acids from ruptured vessels and damaged cells result in toxicity to
the surrounding environment. During this process, secondary cell loss occurs to resident
cells and scar tissue is formed by inflammation cells [6, 7]. The secreted and
transmembrane molecules from scar tissue, in turn, inhibit axon growth [8]. All these
regeneration inhibitors have cross affects on each other at the injury site as shown in
figure 2 [9]. Up to now, though various cellular and molecular strategies have been
used, no single strategy or efficient medical treatment method has been reported to
successfully get full functionality back after injury. SCI is still a complicated
regeneration hurdle that requires further research.
4
Figure 2 Spinal cord injury degeneration process
In recent studies, it is commonly believed that four major principal strategies must
be involved in a “cure” to regenerate the injured spinal cord: (1) Prevent tissue loss and
replace the damaged neurons and glia caused by trauma. (2) Delivery of molecules,
including growth factors or neurotrophins, to stimulate the proliferation and
differentiation of local cells or implanted cell grafts. (3) Prevent secondary injury and
bridge axons to grow out of the lesion site to proper targets. (4) Correct the synaptic
connections [9, 10].
5
Figure 3 Approaching regeneration process
With the aim of achieving better functional recovery, the goal is to create a special
microenvironment that will support these four major principal strategies. In a SCI study,
as depicted in Figure 3, a combination of cellular treatment, delivery of molecules and
other bio-strategies have been reported to approach such principals.
1.2 Time-line for SCI treatment
Previous research also found that, the damage would last for years after the injury
initially happened. Within this time line, it is common to separate the whole time into
three phases, the acute, the secondary tissue loss and the chronic phases [11]. The acute
phase happens right after the injury and lasts for days, during which mechanical injury
to the spinal cord causes local neurons, astrocytes, oligodendrocytes and endothelial
cells to die immediately [12, 13]. The second damage phase, starts within minutes to
weeks after the injury with more complicated reactions. These affects consist of
6
biochemical alterations and cellular reactions. The biochemical alterations include the
release of excitatory biochemical alternations like amino acids, lipid peroxidation and
cytokines [14], and the cellular reactions are caused by inflammation by the over
reaction of immune cells like macrophages, neutrophils and T cells [15, 16]. Results
from the previous two phases continue into the chronic phase. Lost tissue and
inflammation cause the build up of fluid-filled cysts, demyelination, and wallerian
degeneration [13, 15, 16].
According to the injury time line, the first step to repair the damaged spinal cord is
to protect further cell loss and to propagate endogenous cells. Guaranteeing a sufficient
quantity of potential therapeutic cells at the injury site provides a positive environment
to both inhibit scar formation and recruit sufficient number of cells for the next step.
The second period is a long process focusing on guiding the rebuilding of connections.
This is achieved by stimulating the differentiation potential ability of therapeutic
multifunctional cells with specific biomolecules and cell-to-cell contact interactions.
Guided by the surrounding environment, determined types of cells at the injured site
then reconnect together and fix the connection.
7
1.3 Scaffold design
Figure 4 Structure of designed scaffold and distribution of drug location.
1.3.1 Introduction of Designed Scaffold
The scaffolds designed in this project consist of two growth factors encapsulated
in biodegradable co-polymers (either PLGA and PLLA or PLGA and PCL). The two
growth factors are used to mimic the release behavior of biomolecules that stimulate
proliferation and differentiation at different periods of the regeneration process. The
growth factors are located in different places (microspheres or base) of the scaffold. As
Figure 4 shows, the whole device is designed in the shape of a tube. The walls of the
tube are constructed of PLGA as the based material. Microspheres containing GF1, and
GF2 are encapsulated in the PLGA base.
8
The scaffold in Figure 4 has a 4mm outer diameter and a 3mm inner diameter to
match the spinal diameter of rats. The height of the scaffold is in a range of 24.50-25.50
mm (limited by the height of the mold). Each scaffold can be cut to the desired length
with a surgical blade as needed.
1.3.2 Solubility of Material
The scaffold contains different materials of different solubility in aqueous phase or
solvent phase. Biomolecules, like growth factors used in spinal cord injury repairs, are
hydrophilic, and polymers PLGA, PLLA, PCL are hydrophobic. Ethyl acetate is used in
this research because while it dissolves PLGA it does not dissolve PLLA and only
partially dissolves PCL [17, 18]. The benefit derived from this characteristic is
microspheres made of PLLA/PCL can be integrated into PLGA base scaffolds.
1.3.3 Super Critical CO2 Foaming Process
Fabrication of the determined scaffold is based on super critical CO2 foaming
technology. Different solubility and diffusivity of CO2 in polymers make it possible for
two types of polymer-structured drug delivery systems to exist in one scaffold. In
morphology, it is not easy for CO2 to diffuse into crystalline polymers like PCL and
PLLA, therefore the structure of the microspheres are not affected by the CO2 [19].
Amorphous polymer PLGA provides more free volume for CO2 diffusion constructing
the porous structure [20]. When scaffolds, made of PCL/PLLA microspheres with
9
PLGA matrix, are foamed under super critical CO2, PLGA is expanded into the
determined shape based on molds being used, while PCL/PLA maintains its spherical
shape.
1.3.4 Release of Biomolecules
By combining microspheres and PLGA foamed scaffolds together as shown in
Figure 4, the release behavior of GF2 (loaded in the PLGA base) follows that of a
supercritical carbon dioxide foamed PLGA scaffold. The PLGA base, working in a
similar manner as a barrier, slows down the release of GF1 encapsulated in
microspheres, achieving release behavior similar to that of double-walled microspheres.
By integrating different types of deliver systems and co-delivered growth factors in one
scaffold, the initial goal for using this scaffold for spinal cord injury repairs can be met,
with one growth factor released at the beginning and the other gradually released over
time.
1.4 Research Approach
Hypothetically, spinal cord injury can be better repaired when the cell behaviors
are controlled at specific regeneration stages. In particular, a scaffold synthesized with
co-polymer is designed to enhance cell growth, to direct cell differentiation and then in
return to rebuild the connection and to prevent the scar formation at injured site. The
10
first released growth factor is used to recruit and sustain cell growth and the second
released growth factor is used to obtain various desired cell types that are used to
reconstruct the connections at the injury site.
The goal in this project is to design an implant drug delivery scaffold to regenerate
the damaged spinal cord. Working as a delivery system, the determined scaffold is
designed with a benefit of time controllable delivery. Two growth factors are localized
at different places in the same scaffold to obtain different release profiles. The first
biomolecule is to be released instantly after the scaffold is implanted, enhancing the
quantity of cells. A second different biomolecule is ideally to be released later to obtain
various cell types. Co-polymers as fundamental materials, with a sphere in tube
architecture made using a green synthesization process are used in this research.
Enhanced mechanical properties and slowed degradation provide a positive clue for
long-term regeneration studies. Used as a biomolecules delivery vehicle, this scaffold is
specially designed for SCI repairs, however it also has a potential to be used in other
research to deliver two different biomolecules at different times.
1.5 Research Goals
The goals of this project have been listed as follows:
a) To design and to fabricate co-delivery growth factors microsphere-in-tube
structured scaffolds for SCI studies.
11
b) To study release behavior of each growth factor released from the designed
scaffold.
c) To characterize the synthesized scaffolds by morphology, degradation, and
mechanical properties in vitro over time.
12
Chapter2 Literature review
2.1 Cellular Therapy
After SCI, cells are lost at both initial stage and during the following periods.
Cellular therapy used in SCI is to reduce cell death and cyst formation, promote
remyelination of intact axons, overcome the physical impediments preventing the
replacement of lost neural tissue, and optimize the surrounding circulation [21]. All
these functions create a positive environment for regeneration. For these reasons,
certain quantities and various types of cells are required at the injury site. Stem cells are
well known to have the potential of indefinite self-renew and have the ability to
differentiate into all cell types [21, 22]. This differentiation can be guided such that they
will become the type of cell required. Progenitor cells can also differentiate into various
cell types but compared with stem cell they are more restricted in they types of cells
they can become. For example, glial progenitors and neuronal progenitors can be
differentiated into neurons [23, 24]. These multicomponent cells used in cellulose
therapy, have the potential either to self-renew, to replace the lost tissue or to
differentiate into demanded cell types to rebuild the neural connection. This
differentiation can be controlled by the local environment or with stimulation factors.
To repopulate the various cells in the CNS, both the transplantation of exogenous cells
and the stimulation of endogenous multifunctional therapeutic cells have been studied
13
[8].
2.1.1 Different Cell Types Used in Cellular Treatment
Neural Stem Cell/Progenitor Cell (NSPCs), consisting of majorly progenitor cells
and a small amount of stem cells, are located in the ependymal zone and throughout the
peripheral white matter of the adult spinal cord [25]. NSPCs are subculture cell types
from pluripotent cells and can be divided from embryonic neural tissues, induced
pluripotent stem cells, and non-neural adult tissue stem cells [26]. Having the capacity
of self-renew and cellular totipotency, NSPCs can differentiate into neuronal restrict
precursors and glial restrict precursors [27]. Glial precursor cells can differentiate into
glial-based cells and neuronal precursor cells that can differentiate into specific mature
neurons [26]. In in vitro studies, using exogenous cells, NSPCs have been successfully
cultured into neurons, oligodendrocytes and astrocytes [28]. Experiments using human
NSPCs in primate studies indicate NSPCs have the ability to differentiate into neurons,
astrocytes and oligodendrocytes in vivo, indicating this technique is promising for cell
therapy in humans. The various differentiated cells could improve motor functional
recovery without tumors formation [29]. However, one study also indicates the
implanted NPSCs are mostly differentiated into astrocytes [30]. Astrocytes as a type of
glial cells in CNS are activated after injury. The astrocyte proliferation results in glial
scars, which are known to act as physical and chemical barriers for regeneration [31].
To overcome the glial scar, further work has been done to restrict differentiation of
14
NPSCs by using growth factors. Growth factors can provide specific signals; for
example, by delivering bone morphogenetic protein, NPSCs differentiate toward
neurons and oligodendrocytes rather than astrocytes [32]. Similar improvements can be
found by using other growth factors, for example, ciliary neurotrophic factor [33].
Embryonic Stem Cells (ES cells) are subculture pluripotent stem cells, which are
derived from the inner cell mass of the blastocyst. With the ability of self-renew and the
potential to differentiate into a various types of progenitors ES cells are widely used to
enhance neuronal cells including stem cells, neuron, and glial proliferation [34].
Preclinical studies have focused on the advantages of easy to culture and long-term
differentiation potential after several generations by culturing ES cells [35].
Transplanting ES cells into mouse CNS as a preclinical model results in a formation of
oligodendrocytes and astrocytes and indicates a potential ability to restore myelination
[36]. Another clinical study on mice shows ES cells can survive over 50 days after
transplantation and are capable to be used in long-term treatments [37]. ES cells have
the positive characteristics of highly proliferative, unrestricted development, and
sensitivity to the environment; unfortunately these characteristics also mean they have a
high risk of tumor formation [38]. To reduce the over expression of undesired
differentiation, ES cells are not usually directly transplanted in animals but
pre-differentiated into restricted progenitors cells or subculture stem cells, like
oligodendrocytes progenitor cells, neural progenitors first. Then transplant the
pre-differentiated cells are transplanted to treat neurological disorders and traumas,
15
including SCI [39]. For example, oligodendrocytes progenitor cells differentiated from
human ES can generate mature oligodendrocytes and restore myelination [40].
Bone marrow stromal stem cells (BMSCs) containing a subfraction of
mesenchymal stem cells are multipotent stem cells derived from bone marrow
[41]. In SCI studies it has been shown that implanting BMSCs can improve
post-‐injury recover. Working similarly like stem cells, rat and human BMSCs can
differentiate into specific neurons and glia both in vivo and in vitro [42].
Functional BMSCs can aid the neuronal differentiation and at the same time the
secreted neurotrophic factors from BMSCs including, BDNF and NT-‐3 can support
extensive axon growth [43, 44]. Harvested from bone marrow, transplanting
BMSCs in treatment has fewer ethical problems that need to be taken into
consideration.
Schwann Cells (SCs) working to produce the myelin sheaths that surround the
neurons in PNS can promote the axons regeneration. Although SCs cannot be
differentiated into other cell types, the benefit of plastic characteristic SCs also made it
involved in SCI studies. SCs have been investigated to aid regeneration of injured
spinal cords by creating a permissive environment. They aid regeneration both by
limiting the formation of scar tissue, and by accumulating neurite growth promoting
factors, including NT-3, NGF, and FGF at injury site [45]. Evidence suggests that
Schwann or Schwann-like cells are capable to be generated endogenous after SCI [46].
Schwann cell-like cells naturally present at the lesion site are generated by endogenous
16
CNS precursors. The PNSs-derived SCs can also migrate into lesion sites. The SCs
regenerated in the CNS and those that migrated from the PNS together rebuilt the
connection after injury. Transplantation of Schawann cells has also been done on rats
and primates for SCI treatment. However, efficacy and safety issues of using
transplanted SCs in human clinical trials haven’t been reported yet [8].
Olfactory Ensheathing Cells (OECs) are glial cells generated from embryonic,
adult olfactory bulb, or mucosa. OECs play an important role in the lifelong neural
regeneration capacity of olfactory neurons in SCI studies [47]. OECs can create a
permissive microenvironment at the injury site and enhance the migration of sprouted
axons in damaged CNS tissue. The migration of sprouted axons within the spinal cord
can reduce the cavity formation and lesion size [48]. There are a few clinical
experimental studies using OECs for CNS neuronal regeneration. Implanting human
OECs into rodent spinal cord injuries improves the remyelination [49]. SCI studies
show OECs can improve long-distance growth of axons, which can be used as a
therapeutic application in CNS [50].
2.1.2 Exogenous-based Therapies for SCI
To harvest a high quantity of therapeutic cells, some recent studies focus on
culturing various types of exogenous precursors, including both stem cells and
progenitor cells [51, 52]. These stem cells or multi-differentiated precursor cells can be
cultured in vitro into a three-dimensional structure named ‘neurospheres’. These
17
spherical shaped cells are diverse collections of glial and neuronal precursors with a
potential to differentiate into multi-desired cells at an injury site [23, 53].
Though the benefit of this technique results in simple cell replacement, there are
still some concerns on the overall ability of using implanted multifunctional cells at the
injured spinal cord. There are several preclinical safety studies on transplanted
cell-based therapies for SCI. Although there are benefits of using pluripotent cells to get
various therapeutic cells, it also causes the undesired phenotypes resulting in a major
safety concern to SCI treatment. Although transplanted stem cells have the ability to be
differentiated into neurons and oligodendrocytes, stem cells can also promote the sprout
of undesired sensory fiber within the spinal cord [38]. Other safety concerns related to
the use of transplanted cells are immune rejection and apoptosis. Cell-death associated
inflammatory response and toxicity to local tissue bring a high risk of side effects for
SCI regeneration [54]. Teratomas, caused by the rapid generation of undifferentiated
stem cells, form large tumors, which is safety, concern, therefor limiting the usefulness
of exogenous stem cells for SCI treatment [55]. Studies on SCI by using NSPCs found
the implanted cells have the ability to migrate to a number of the other CNS structures,
which could potentially lead to undesired side effects [24, 56]. Considering all the listed
risks, using cell transplanted-based therapy for SCI need to overcome regulatory and
manufacturing hurdles for commercial and clinical use.
18
2.1.3. Endogenous-based Therapies for SCI
Progenitor cells exist in adult human body, which have capacity of producing new
neurons and glial cells and can be used as a potential source of cells to replace the
degenerated ones [57, 58]. Specifically in the spinal cord, the population of the
endogenous cells is significantly reduced after trauma [59]. This dramatic neurogenesis
loss is one of the common findings of all proliferation studies in adult spinal cord
studies [60]. Around the trauma site, the progenitor cells from near by tissue could be
stimulated to proliferate and to migrate toward the injury site. Progenitor cells are born
every day in the spinal cord. After injury, cell birth gets a trend to be enhanced [4].
Although the newborn cells likely replace part of the lost cells, functional recovery is
still restricted by their sensitivity to the surrounding environment [61]. Another study
indicates that endogenous progenitors are differentiated into glial cells, rather than
neurons that, depending on their type, can also inhibit the regeneration [62].
The properties and function of endogenous NPCs are governed by both cell-to-cell
contact interactions and through a multitude of molecular signals including growth
factors [63], cytokines [64] and bone morphogenetic proteins [24, 56]. Deliver of a
combination of molecules can promote the survival of endogenous NPCs and direct
their cell fate, such as maximum proliferation or differentiation [21]. For instance, in
previous studies EGF and FGF delivered to injured spinal cord promoted endogenous
NPC survival and directed their cell fate [65].
19
Using transplanted cells for SCI treatments have been limited by scar formation
due to immune response, and inhibited cellular expression. A benefit of using
endogenous cells genetically matched to the injured tissue, is that they may reduce the
immune response and eliminate an ethical hurdle. There are several approaches trying
to enhance the functional recover after SCI. Using enzymes to break down the scars or
to deliver growth factors to awaken the regeneration capacity of progenitor cells around
the injury site both of which have the potential ability to achieve functional recovery
after SCI [4].
2.1.4 Conclusion
Besides the individual problems mentioned above, use of cellulose treatment has
also been generally limited by undesired differentiation and limited mechanism in local
tissue. Research proved that even the restricted neural stem cells would differentiate
primarily towards glial cells rather than neuron cells without specific molecular
guidance [29, 66]. Therefor, molecular modification or the use of pharmacologic agents
as guidance is important to cellular therapy to achieve the desired tissue regeneration
[67]. Mechanism of cells or newly generated tissues is not supportive enough to the
surrounding environment. In general, practical research should provide a material that
can enhance the cellulose therapy by creating a certain surface to localize implanted
cells or to use as a delivery media to prevent damage caused by pressure from
surrounding tissue [68]. As a result, cellulose therapy can hardly be approached
20
individually. Discovery of a proper delivery system will enhance the result of cellulose
treatment.
2.2 Molecular Therapy
Delivery of therapeutic molecules has been used by tissue engineering in different
regeneration procedures. Along with a proper delivery procedure, various biomolecules
can effectively encourage regeneration of endogenous cells or exogenous cells at the
demanded site.
For SCI, molecules are mainly used for four purposes. 1. Protecting the surviving
axons. 2. Overcoming the inhibitory factors for regeneration. 3. Stimulating
proliferation of newly grow neurons. 4. Differentiating stem cells into the required cell
types in surrounded environment [69]. To date, many studies have shown the positive
effects by delivering one molecule or combined molecules with therapeutic cells in
combination therapy.
2.2.1 Protecting the Spinal Cord
The pathophysiology of SCI is a complicated process in regeneration. One of the
barriers in current research is the inflammation caused by the immune response around
the injury site. In clinical research, delivery of the anti-inflammatory drug
methylprednisolone provides several potential benefits to avoid deleterious effects [47].
21
Erythropoietin (EPO) is a glycoprotein hormone. Cooperating with various other
growth factors in erythropoietin, EPO has various functions including promoting
angiogenesis, proliferating smooth muscle fibers, and protecting neurons [70]. It can
also control inflammation by decreasing lipid peroxidation at the injury site [71]. Using
EPO for treatment can functionally increase the level of hematocrit, which may
decrease the lesion size [72]. For such reasons, EPO has been involved in further
investigation as a neuronal protective molecule for SCI.
Minocycline is a broad-spectrum tetracycline antibiotic with a potential function of
anti-traumatic inflammation [73]. Minocycline treatment is mainly used for the
purposes of encouraging axonal sparing, reducing lesion size and cavitation [74].
Minocycline can reduce apoptosis of oligodendrocytes and can inhibit the production of
microglia. Both of these functions may improve the recovery after SCI [75].
Interleukin-‐10 (IL-‐10) is a homodimer protein and it works as anti-inflammatory
cytokine with pleiotropic effects in immunoregulation and inflammation [76].
Presenting IL-10 can reduce the lesion size and can protect the SCI site from secondary
damage [77]. It has been demonstrated that IL-10 can activate neuronal IL-10 receptors.
Activated neuronal IL-10 receptors then provide trophic support and survival cues to
overcome the toxic effects on neurons [78].
2.2.2 Overcoming Inhibitions
After SCI, cell loss encourages the cellular reactions by increasing the inhibitors
22
around the injury site. Inhibitors directly stimulate the glial scar formation and
encourage the build up of a physical barrier for axonal outgrowth of the injury [47]. For
such reasons, overcoming effects given by the inhibitions after injury is a main subject
in SCI studies.
Chondroitinase ABC (ChABC) is an enzyme catalyst and it is involved in various
chemical reactions including the degradation of chondroitin sulfate proteoglycan
(CSPG). CSPGs are the principal inhibitory component of glial scars, which are highly
enriched at an injury site [79]. It works by activating the behavior of astrocytes, which
inhibits the neurite outgrowth both in vitro and in vivo [80]. ChABC has been used to
degrade CSPGs in some pre-clinical experiments to provide a permissive environment
for axon regeneration [81].
Myelin-‐associated Glycoprotein (MAG) is a trans-membrane glycoprotein
localized in periaxonal Schwann cells and oligodendroglial membranes of myelin
sheaths. It works as an axonal receptor needed for the maintenance of myelinated axons,
and it also works as an axonal signal to promote the differentiation and survival of
oligodendrocytes [82]. Briefly, it has a significant positive effect in glia-interactions
and myelination.
2.2.3 Stimulating the Axonal Growth
Molecules are strongly related to cell growth, guidance, and existing through out
the treatment. Growth factors are either proteins, steroidal hormones, or are a naturally
23
occurring substance, all of which are capable of stimulating cell proliferation,
differentiation, migration, adhesion, and gene expression [83]. They are widely used to
stimulate axonal growth. Neurotrophic factors, including nerve growth factor (NGF),
brain-delivered neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) have been used
to promote axonal growth individually or together. To achieve similar functional
recovery other growth factors, for example fibroblast growth factors (FGF), epidermal
growth factor (EGF), and Glial cell line-derived neurotrophic factor (GDNF), have also
been used to enhance axonal growth.
Nerve Growth Factor (NGF) is a secreted protein used as a signaling molecule to
enhance growth, and to maintain the survival of nerve cells [84]. The effect of NGF is
strongly related to the population of the where TrkA receptors located [85]. In
neuroprotection and neural reparation, NGF plays an important role in the response to
injury or disease [86]. Recently there is also a conflict in using NGF for treatment. NGF
can lead nociception in SCI models and may induce autonomic dysreflexia [87].
2.2.3.2 Neurotrophin-3 (NT-3)
NT-3 is the third neurotrophic factor in the NGF family. NT-3 has been proven to
support the surviving neurons and to stimulate the newly generated neurons [88].
Similar to BDNF, NT-3 works by improving the descended neurons caused by injury,
sprouting of spared fibers, and enhancing myelination [89]. The presence of NT-3 also
increases the amount of pligodendroglial tissue by reducing the astrogliotic and
24
microglial responses [90].
Brain-‐delivered Neurotrophic Factor (BDNF) is a series of secreted growth
factors that can promote and support the survival of existing neurons and encourage the
proliferation and differentiation of new neurons in both CNS and PNS [91]. Using
BDNF can also improve the environment for axonal growth at the injury site by
degrading growth inhibitors. Delivery of BDNF can prevent retrograde atrophy of
neuronal cells as well as the over express of immune response which inhibits
regeneration [92]. All these functions may enhance the axons beyond the lesion site and
remeylination in SCI treatment [93]. In clinical trails, there are also evidences indicate
that, BDNF therapies have yielded good results in animal models, as well as in
underway human subject studies [94].
Besides using individual neurotrophic factors for SCI treatments, deliver of
combined neurotrophic factors are also showing positive results to enhance
regeneration. Deliver of BDNF and NT-3 have been reported to have the ability to
enhance spinal axonal regeneration of a specific population of brain stem neurons [95].
NGF and BDNF together can develop and protect surviving neurons at specific
peripheral and brain locations [96]
Fibroblast Growth Factors (FGFs) are belonging to a family including over
twenty members working as structurally related signaling molecules [97]. FGF2, known
as FGF-b is widely involved in neuronal protection, neurite outgrowth enhancement,
and axonal survival regeneration [98]. The use of FGF in another study promoted both
25
survival of existing neurons and neurite outgrowth of identified neuronal subtypes [99].
There is no positive clue to promote substantial regeneration by using EGF individually
[100]. Delivery of both FGF-2 and EGF together, based on synergic effect of the two
growth factors, has been reported to have the function of stimulating the proliferation of
neural precursors [52, 101].
Glial Cell Line-‐derived Neurotrophic Factor (GDNF) is a protein used to promote
the survival and differentiation of neurons from progenitors, as well as to prevent
apoptosis of motor neurons [102]. Therefore GDNF has been involved in current
research as a potential therapeutic agent for the treatment of neurodegenerative related
SCI [103]. Using GDNF can also promote survival of other neurons, for example,
central spinal motor neurons, sensory neurons, and non-adrenergic neurons [104].
However, due to the inadequate diffusion of GDNF in clinical treatment, up to now,
using GDNF individually has been confirmed not to improve the functional recover
[105].
2.2.4 Cell Differentiation
To date, most recent research focuses on delivery of molecules to stimulate
multifunctional stem cells or progenitor cells for cellulose therapy. A signal to guide the
behavior of cell growth into a desired connection is required. To promote differentiation,
different types of molecules have been used in previous studies.
Vascular Endothelial Growth Factors (VEGFs) is a signal protein with functions
26
to stimulate the vasculogeneses and angiogenesis. It works by creating new blood
vessels during embryonic development and after physical injury to bypass blocked
vessels [106, 107]. The expression of VEGF receptors in the endothelium of both
developing and mature blood vessels suggests that VEGF might regulate endothelial
differentiation, blood vessel growth, and vascular repair [108].
Platelet-‐derived Growth Factor (PDGF) is one of the protein-based growth
factors regulating cell growth and division. PDGF has five individual forms including
PDGF-A to PDGF-D, and homo- or hetero- of PDGF-AB (PDGF-AA, PDGF-BB, and
PDGFAB) [109]. Responding through specific binding of PDGFs to PDGF receptor-α
or PDGFR receptor -β, delivery of PDGFs play distinct roles in differentiation and
development of the progenitor cells [110]. Using PDNF to direct meshenchymal
proliferation successfully guides the migration and differentiation during development
and in adult animals [111]. There is also evidence to indicate infusing PDGFs to adult
CNS functionally supports neuronal differentiation [112]. All these positive results
make PDGF popular in SCI research.
Transforming Growth Factor-‐β (TGF-‐β) is a superfamily of secreted proteins,
including inhibins, activin, anti-mü llerian hormone, bone morphogenetic protein,
growth/differentiation factors, decapentaplegic, and Vg-1 [113]. This family of
molecules have been involved in various biological actions including cell-cycle control
differentiation and immune responses [114, 115]. In CNS, three isoforms of TGF-β
(TGF-β1, TGF-β2, TGF-β3) are produced by glial and neuronal cells. They have been
27
found to regulate essential tissue functions in early development and differentiation,
neuron survival and astrocyte differentiation [116]. TGF-βs are not neurotrophic in
general, but when working with other molecules like FGF-8 or Sonic hedgehog (Shh)
together, they exhibit a great promotion for neuronal survival [117]. BMP, a member of
the TGF-β family, also promotes neuronal differentiation of cortical ventricular zone
precursors [118].
Int/Wingless (Wnt) proteins are belonging to a family of secreted lipid-modified
signaling glycoproteins. This family consists of over 17 members and works on the
development of CNS [119]. Wnt signaling appears to regulate cell proliferation,
apoptosis, migration, and differentiation, which greatly enhance the CNS regeneration
[120]. As an essential component of the canonical Wnt signaling system, catenin has
been used with different concentrations to guide neuronal progenitors to proliferate or
to differentiate [121]. In another study, Wnt has been shown to have the function of
leading multifunctional cells to be be less likely to differentiate into oligodendrocytes
and astrocytes, which may enhance neuron regeneration [122].
Sonic hedgehog (Shh) is a multifunctional growth factor working in several
functions to repair an injured spinal cord including cellular differentiation and
proliferation [123]. Shh, providing guidance for neuronal cell differentiation, aids to
create a permissive environment. With the delivery of Shh, ventral cord progenitor cells
are guided to differentiate into motor neurons and oligodendrocytes. Shh is also found
to have the function of leading the axon guidance [124]. Therefor, Shh inhibits the
28
differentiation of progenitor cells into astrocytes thus reducing scar formation. All
these effects in return stimulate myelination and promote neurons survival after SCI
[125].
Retinoic Acid (RA) is a metabolite of vitamin A. It has been investigated in
serving as a trigger for pre-existing coordinated pathways of neural gene expression,
and for inducing neural differentiation [126]. Treatment with high RA concentration
has the ability to promote the differentiation of neuronal progenitors into olfactory
neuronal cells [127]. RA has been also used to induce posteriorization of ES cells
derived neural precursors and to promote differentiation of neural crest derivatives
[128]. For these reasons, RA has been considered as an important extrinsic inductive
signal that can be used for neural differentiation [127].
2.2.5 Conclusion
In previous research, delivery of individual molecule treatments have been done in
SCI, however, with the problems associate with the simple molecule treatment achieved
only limited functional recovery. Since the SCI cannot be solved by delivery of any one
molecule, the combination therapies came into research field by increasing permissive
cues together with reducing non-permissive ones at the same time. As all the different
purposes of using molecules in treatments, there are many possible ways to operate the
combination procedures. However, how many therapies can be combined and how
much invasiveness can be limited are the main concerns in practical research [85].
29
Protecting survived cell growth, slowing down inflammation and stimulating
axonal regeneration need to be done in SCI [10]. According to injury time line, all these
requirements are distributed in different periods of the regeneration stages. For such
reasons in combination therapy, an on-demand delivery of molecules is required. A
delivery system with the ability to sequentially co-deliver molecules in different
demanded periods is an essential requirement in combination therapy.
2.3 Delivery of Growth Factors
Growth factors are a group of critical molecules that provide instructions that
guide cell development. In tissue engineering including SCI repairs, they have been
used to direct cell behaviors, for instance, stimulating cell migration, growth and
differentiation [129]. To date, many studies have shown the positive effects by
delivering one biomolecule or combined biomolecules in different therapies.
In the previously spinal cord injury studies, one of the limitations of regeneration
is observed due to insufficient growth factors support and unregulated level of axonal
growth inhibitors [129]. The growth factors, having the characteristic of short
biological half-life, require a different mode of delivery than other polypeptide [130].
Therefore, delivering growth factors at the target location at an appropriate time, at a
specific concentration and at a specific rate of delivery affects the final regeneration
results. For these reasons, extracellular matrices (ECMS) are involved in most of the
30
growth factor delivery system design.
The release rate of growth factors are based on the diffusion rate of the growth
factor from the ECMS material and by rate of degradation of the ECMS material.. In
tissue engineering, the specific types of growth factors to be delivered, the
time-dependent delivery schedule and the sequential release of growth factors strongly
affect cell migration, differentiation and proliferation [130, 131]. The control-released
growth factors need to meet the demands of local environments to optimize the
efficiency of reparation.
2.3.1 Co-deliver Growth Factors at Same Time
Individual growth factors have their individual functions based on target tissue.
Combining appropriate growth factors together has several potential advantages, for
example, synergistic effects on growth factors, suppression of drug resistance, and
balances the dosage of drugs [132]. Co-delivery of multiple growth factors has been
widely used in tissue engineering. It has a more promising future to handle complex
process treatments than single growth factor treatments [133].
Co-delivering two factors has been used in a wide range of research fields. To
attain the desired co-deliver results, different delivery vehicles also have been designed
and tested. In general, most studies first mix the growth factors together and then
integrate them into various deliver systems. The mixed growth factors are mostly
chosen with the same characteristics. To achieve simple access to the injury site, the
31
mixed growth factors can be easily delivered by injection, infusion, or (if they are
mixed into the scaffold material during the manufacturing process) by diffusion.
Specifically in the studies on SCI, delivering two growth factors can provide better
results than delivering a single growth factor. In many studies NT-3 or BDNF have
both been shown to provide similar positive effects on the extent of axonal growth from
multiple channel scaffolds [129, 134]. It has been demonstrated that simultaneous
delivery of NT-3 and BDNF together results in increased neuron survival rates
compared with individual delivery [95, 135]. Positive results were also found when
delivering combined NGF and BDNF together. Results indicate co-delivering two
growth factors can develop surviving neurons at specific peripheral and brain locations
[96]. Fibroblast growth factor-2 (FGF-2) used with epidermal growth factor (EGF) has
been reported to stimulate the proliferation of neural precursors [52, 101]. All these
positive clues light up the regeneration process by co-delivering two growth factors to
injured spinal cord.
Delivering three or more growth factors can be integrated into scaffolds by
soaking the dry scaffold into a mixed growth factors solution. For example a scaffold
consisting of alginate-sulfate/alginate, vascular endothelial growth factor (VEGF),
platelet-derived growth factor-BB (PDGF-BB) and transforming growth factor-b1
(TGF-b1) has been proved functionally superior to delivery of FGF-b only [136].
Although the scaffold has more growth factors inside, in many studies, the poor release
control from the scaffold limited the potential benefits. A follow-up study needs be
32
done to compare the benefit of three growth factor delivery scaffolds versus with two
growth factor delivery scaffolds.
Delivery of specific combined growth factors in recent studies indicates improved
functional recovery versus delivery of individual growth factors. Additionally, most
multi-treatment injury studies require sequential delivery of different growth factors at
different times in order to achieve optimal regeneration.
2.3.2 Sequential Delivery of Growth Factors
In several medical fields, regeneration studies indicated that sequential release of
growth factors or small molecules achieve better regeneration than delivery them at the
same time. In bone regeneration, sequential release of BMP-2 with BMP-7, BMP-2
with VEGF, IGF-1 with TGF-β1 has been studied by encapsulating these growth
factors into different delivery systems [131, 137, 138]. Positive results indicate delivery
of multiple growth factors sequentially can affect different cell behaviors. Enhanced
proliferation and stimulated differentiation on an injury site both affect bone formation.
Similar sequential release has also been done in angiogenesis studies. Release of
VEGF-A165 [139] followed by PDGF-BB, angiopoietin-1 (ANG-1), or TAT-HSP27
(transcriptional activator) [140-142] has shown functional improvements after
myocardial infarction. Individual delivery of VEGF growth factor can stimulate the
blood vessel formation, but forms immature or shot-lived blood vessels. Subsequent
release of growth factors like HGF, PDGF-BB, or ANG-1 can recruit mural cells
33
around the new vessels to strengthen them [140]. Thus, sequential delivery of two
growth factors can produce more mature blood vessels and improved functionality of
the networks. Multifunctional sequential drug delivery systems have also been designed
to deliver combinations of drug and drug, drug and peptide, and RNA and RNA in
anticancer studies [143]. In anti-cancer studies, the surface modified agent can
recognize the target site first, and then the attached particles can deliver the
encapsulated drug at the target site. This delivery system has a potential to reduce the
toxicity of encapsulated drug working on non-target cells in the environment and it has
greatly improved the efficiency of target site drug delivery [143].
In SCI studies, following the time line after injury, it has been shown that the
sequential delivery of growth factors can be used to prevent degeneration of cells. This
was achieved by first delivering one specific growth factor to promote cell proliferation,
and then delivering another specific growth factor to differentiate the expression of a
desired phenotype [138]. Specific to spinal cord studies, the extra requirement of
specific required mechanical properties makes it more difficult to design a desired
scaffold in an appropriate structure [130].
Several structures have been studied to achieve sequential release of different
growth factors. One of the sequential release models that has been tested used
multifunctional particles having one drug encapsulated inside the particles and another
drug attached to its surface.
34
2.3.2.1 Sequential Release from Particles
The multifunctional drug delivery particle shown in Figure 5 is composed of a
central core with small hydrophobic drugs encapsulated inside and branches of
hydrophilic agents attach to the surface. The release behavior from these particles is
determined by the order in which they are assembled. The first drug located on the
surface of particles having ability to target the cells or tissues is released first, and the
other drug encapsulated in particles will gradually release due to diffusion and
degradation of the polymer shells. The slight difference in time (5-20 hours) with 20%
dosage to release the surface attached drug and encapsulated drug has been teasted by
delivering decetaxel (Dtxl) and doxorubicin (Dox) [132]. The purpose of using
multifunctional particles in most of the similar research is to achieve simultaneous
synergistic effect, in order to enhance tumor vasculature targeting [144-146]. Particle
sizes in multifunctional systems are usually designed to be 1-200 nm in diameter.
Considering biodistribution and toxicological profiles of any nanoparticles may arise,
which could limit using nano size particles in treatments in other fields [147]. Thus,
localized co-delivery of factors has potential to increase the safety and efficacy of
growth factor-mediated techniques [148]. Sequential release particles are generally used
in anti-cancer studies for the purpose of short-duration on target delivery. As a result,
few research studies have focused on long-duration controlled release of molecules,
including SCI studies.
35
Figure 5 Scheme of two molecules sequentially release from multifunctional particles as drug carrier
2.3.2.2 Sequential Release from Extracellular Matrices
There are several research approaches to release drugs sequentially from
extracellular matrices. The design of the structure, controls the directions drugs can be
sequentially released from the matrices. The next three sections describe structures that
can sequentially release molecules in one, two, and three dimensions.
1)One-dimensional release is achieved by encapsulating different drug layers in a
well structure as shown in Figure 6. This well-capped system provides release of drugs
just from the top. Ideally the drug placed closest to the surface drug released first,
followed by the drug placed at the bottom of the well. The combined titania nanotube
(TNT) arrays and the polymer micelles implant has been used in nano-engineered drug
delivery systems. Working as a multi-drug carrier, it has ability to sequentially release
36
different drugs. The different orders drugs in polymer micelles arranged in the device
affect the time drugs been eluted [149]. Another similar design to release growth factors
sequentially is to load different growth factors in different surface-eroding polymer
layers. These layers of polymers are placed in a polystyrene well. Doxycycline loaded
in bottom layer is released after simvastatin loaded in the top layer, which makes a
small difference in their release times [150]. The use of this type of structured device is
limited in tissue engineering because:
• drug delivery is not uniform in all directions,
• the nano size device is difficult to place drugs in by layers
• the well must be removed after drug delivery is complete.
Figure 6 Scheme of two molecules sequentially release from polymer well as a drug carrier
37
2)Two-dimensional release is achieved by layer coating lengths of scaffold
material, as shown in Figure 7. The synthesized sandwich structure system allows
multiple layers to be used to deliver different drugs at different times. The sequence
of different drugs released is determined by the layer they are encapsulated in. Basically,
drug in the outer layers has short diffusion distance to the aqueous environment and
releases first. The release of the other drug located in the inner layer is delayed by the
degradation of the polymer and sandwich structure, resulting in sustains the release
fashion. This two-dimensional deliver system has been tested by various studies.
Using trimethylene carbonate (TMC) based elastomers with an osmotic
mechanism release, two growth factors have been used to proliferate of human aortic
endothelial (HAEC) and CCL 208 monkey lung epithelial cell lines [141]. Using this
system, although VEGF released slightly faster than hepatocyte growth factor (HGF) in
the first two days, after the first two days similar release rates were observed for both
growth factors.
A different study used a gelatin coating technique to make two similar structures,
one to deliver BMP-2 followed by IGF-I, and one to deliver BMP-2 IGF-1at the same
time [151]. This test indicated sequential release has positive results in cell culture
studies, compared with simultaneous release. Unfortunately no release profile was
published.
Coating different concentrations of poly (D, L-Lactide) (PDLLA) layers with
BMP-2, IGF-I and gentamicin loaded has been used in other studies to synthesize
38
implants for soft tissue regeneration. The drug loading implants are designed to release
sequentially depending on the order they coated on titanium Kirschner wires (K-wires)
[152]. This design has a potential to sequentially release more than two growth factors,
but current results indicate the system has poor release control. The time difference
among growth factors happened in the first two days and the all of the release finished
in three days.
Figure 7 Scheme of two molecules sequentially release from coating based two-dimensional drug carrier
3)For the three–dimensional sequential release case, more types of structures
have been designed. These studies take advantage of the fact that different drugs have
different release rates from the same or different types of materials. Different
39
techniques are used to synthesize these drug delivery systems and the release of
different drugs at different times is achieved by combining the different drugs in
different gels or particles. The most commonly used three-dimensional release structure
consists of multiple drugs or drug loaded particles suspended in gels, as shown in
Figure 8.
In Figure 8 A, the gel can first release encapsulated drug from system, followed by
the drug from small particles. In a bone regeneration study, IGF-1 (drug 2) has been
first loaded in gelatin microspheres then integrated in a chitosan gel together with
BMP-2 (drug 1)[153]. Release of BMP-2 from chitosan gel has an initial release, and it
is followed by a sustainable release of IGF-1 from the microspheres. In soft tissue
regeneration, interleukin-2 (IL-2) is incorporated into alginate microspheres. These
microspheres are then coated with CpG oligonucleotides to form a sequential release
system. These microspheres are then suspended in alginate gel solutions [154]. The
CpG located closer to the surrounding environment releases sooner than the IL-2.
In Figure 8 B, two types of drug encapsulated particles are localized in the same
gel. This system has been done in two different cases: using different drugs separately
encapsulated in the same type of material, and using different materials to encapsulate
different drugs. In a brain tissue regeneration study EGF encapsulated in PLGA
nanoparticles and erythropoietin (EPO) encapsulated in PLGA nanoparticles coated
with poly (sebacic acid). Then the mixed particles are dispersed in a hyaluronan
methylcellulose (HAMC) hydrogel [155]. With the coting of poly (sebacic acid) EPO
40
receives better physical release control and it releases slower than EGF from not coated
PLGA nanoparticles.
Figure 8 Scheme of two molecules sequentially release from particles in gel structured three-dimensional
drug carrier
A model of combine alginate hydrogels in different molecular rate together has
been used to deliver VEGF-A and PDGF-BB. Using a high molecular weight alginate
hydrogel with PDGF-BB; and a low molecular rate alginate hydrogel with VEGF-A are
combined together [156]. PDGF-BB was found to be released more slowly than
VEGF-A in first three days, but afterwards this delivery system has similar growth
41
factor release rates for both drugs due to the use of same gel as the based material.
Microspheres can be combined together through a certain technique to synthesize a
scaffold. In a study of PLGA microspheres, IGF-I and TGF-β1 are separately
encapsulated using a spontaneous emulsion method. Each type of microsphere is
individually used to fabricate a scaffold with dichloromethane vapor method [138].
During release study, IGF-I is released faster than TGF-β1 first fifteen days, and then
both growth factors will keep releasing until releases complete in 60 days.
In general, three-dimensional release systems provide longer controlled release of
sequentially co-delivered growth factors than other systems. For use in treatment, by
changing the base material of the microspheres, the release rate for different drugs can
be separately controlled. This has positive implications for multi-step therapies.
Never the less there are some technical limitations by using current three-dimensional
delivery models. As we mentioned in Figure 8, the gel-structured base has low
mechanical properties and poor drug release control. There are few studies that report
using other materials or fabrication processes to create three-dimensional sequential
release scaffolds
2.3.3 Controlled Release
In sequentially co-deliver growth factors system, most devices or scaffolds are
made from natural polymer gels, such as collagen, chitosan, and hyaluronic acid starch.
These natural materials are mostly soluble in water and can be fabricated in relatively
42
mild conditions [157]. In tissue engineering design, these materials also have some
common problems limiting use as delivery vehicles. These gels degrade quickly which
leads to rapid and burst release of growth factors as well as fast decrease of their
structural properties [158]. On natural polymers, increasing the molecular weight
distribution, modifying gels with chemicals, and blending polymers together have been
done to control the undesired release profile [130].
Synthetic polymers including a member of the α-hydroxy acid class of compounds,
poly (glycolic acid)(PGA), poly (L-lactic acid)(PLLA), poly (lactic acid-co-glycolic
acid)(PLGA), poly (lactide-co-caprolactone)(PLCL), and poly (ε-caprolactone)(PCL),
have been made into nano/microparticles by using the emulsion-solvent evaporation
technique [159]. Simply by encapsulating particles into another polymer to form
core-shell structures one can efficiently control the release profile. As shown by the
results listed in Table 1, sustainable release has been achieved and initial burst has been
reduced.
Material Encapsulated
durg
Results
PLLA/PLGA Hydrophilic
abtibiotics
40% cumulative drug release for 30
days[18]
PLGA/CS Protein Reduce initial burst and extend
43
release[160]
PLA/PLGA Hydrophobic
drugs
Extend to week-to-month controlled
release[161]
PLGA/PLA GDNF Sustain delivery of bioactive GDNF
over 50 days[162, 163]
POE/PLGA BSA and CyA CyA released faster due to double
walled structure[164]
Table 1 Sustainable release from double-wall microsphere
Based on the core-shell control release theory, regular microspheres could be
integrated into scaffolds, if made of the same material as the shell in core-shell
structured microspheres. The acaffold base can now work as the shell providing
long-term sustainable release.
2.4 Scaffold Delivery Systems
Different strategies have been used to repair damaged spinal cords. The
introduction chapter promising treatments are listed in recent research. When doing
practical treatment, a delivery system is required to integrate cellulose therapy, delivery
of biomolecules, or both into the injured site. A well-designed delivery system, having
the ability to control the release in the treatment site, can achieve maximum results
44
when combined with positive elements found in current studies.
2.4.1 Co-delivery Systems
2.4.1.1 Mini-pump
An osmotic mini-pump is implanted in vivo, by taking advantage of the osmotic
gradient between the tissue and the pump, to infuse determined delivery agents. With a
catheter, the pump can deliver liquid molecules directly into the venous or the arterial
systems. These pumps have been used to deliver growth factors to aid in promoting
neurons to regenerate at a specific time and place. Brain-derived neurotrophic factor
(BDNF) [4] and neurotrophin-3 (NT-3) [135] have been delivered using mini-pumps.
The benefits of using mini pumps are their small size and ease of access. However,
inflammation caused by using mini-pumps has been reported to block the catheter [165,
166]. After therapy, another surgery is required to remove the mini device. This extra
surgery causes additional damage to the local tissues. To date, no research has been
done to transplant cells by using a mini-pump at the injured site. The required extra
surgery and a risk of inflammation limit the use of osmotic mini-pumps in SCI repairs
in current research.
2.4.1.2 Oral
Oral delivery of growth factors is the most straightforward way for treatment.
Benefits of oral deliver include easy access and time control [167] therefor oral delivery
45
has been used in early research. Positive results have been reported by taking growth
factor orally. Taken orally, a sufficient quantity of derived growth factors can reach the
injury site to effect treatment [168]. When taken orally, due to their poor absorption rate,
an increased consumption dosage of biomolecules is required. This large general
concentration of biomolecules in the blood, may result in potential side effects, and
may affect non-target tissues in long time therapy [161].
2.4.1.3 Injection
Injection can deliver biomolecules and cells directly into the injury site, strongly
enhancing local regeneration. Injection has proved to provide positive results in
delivery of both liquid biomolecules and cell loaded injectable gels. According to the
limit by using a catheter through injection, a solution or non-concentrated gel is
required as foundation material [101, 169]. Release of biomolecules from low density
solutions cannot be well controlled, with release finish right after injection, thus greatly
limiting their use in long-term treatment [4]. Multiple injections have been used to
overcome this disadvantage, but having the added risk of causing extra damage to the
local tissue.
2.4.1.4 Scaffold
Specifically in SCI, historical research proved that without tension between the
tissues, surgical treatment could reconstruct the nerves, transfer tendon, and muscle to
46
help recovery [170]. However, after injury, a nerve gap (less than 5mm) caused by
sutured back ends of tissue creates a hurdle for using surgical treatment without a
bridge [171]. For such reason, scaffolds are involved in the design of recent research.
Nerve guidance scaffolds have been widely used in combination therapy. Working
as a bridge in between damaged tissue, scaffolds have the advantages of preventing scar
formation, supporting attached cells, and delivering molecules. In cellulose therapy,
work has been focused on portfolio strategies including direct cell implants,
pre-cultured tissues implants, and direct in situ tissue regeneration [172], in which
scaffolds were used as a foundation. Biomolecule-encapsulated scaffolds can be used as
carriers, thus enabling biomolecules to be sustainably released at the specific site with
the benefit of minimizing systemic blood-drug concentration related side effects [173].
Scaffolds can provide a substrate to fill cystic cavities [174] and to slow down the
formation of scar tissue and lesion build up [175].
Previous studies also obtained positive results from integrating different elements
together in one delivery system. The combination of using encapsulation cell
technology (ECT) of immobilized therapeutically active cells [176] and bidirectional
diffusion of molecules [173] within a three-dimensional microenvironment matrix
between the damaged tissues has been studied in recent research [177, 178]. Better
functional recovery has been achieved by using such multi-therapy integrated
biomaterial scaffolds in treatment [179].
To avoid problems with using scaffolds as an implant device, some additional
47
critical elements need to be taken into consideration during the design. Biocompatibility,
adequate biodegradability, mechanical properties, low toxicity, malleability, and ease of
manufacture [180] are commonly used to qualify a scaffold in tissue engineering [181].
2.4.2 Materials
Scaffolds synthesized of proper materials can efficiently bridge the nerve gap by
creating a microenvironment similar to local tissue thus promoting cell growth and
differentiating the multifunctional cells with permissive surroundings [178]. To rebuild
the microenvironment, both natural and synthetic materials have been tested in research.
There are several critical properties in choosing materials for research that need to be
taken into consideration at the beginning of the design. Firstly, the scaffold must be
constructed of a biocompatible material. Using such a device implanted in vivo,
minimizes the chances of inflammation or allergic reactions caused by the immune
system. Secondly, materials with the ability to deliver biomolecules and encourage cell
attachment provide better modification possibility. Thirdly, the material should be
strong enough through out the reparation period to avoid secondary damage that could
be caused by premature scaffold collapse.
2.4.2.1 Non-degradable Materials
Non-degradable materials benefit from being simple to synthesize, having fewer
batch differences [159] and remaining stable in vivo. After the fabrication process, all
48
the parameters can be well maintained, particularly the mechanical properties will not
change over time. Additionally non-degradable materials are superior to degradable
materials, because they produce no toxicity degradation products, therefor allowing
them to be used in implant device design. In current research, commonly used
nondegradable materials are poly (2-hydroxyethyl methacrylate) (PHEMA [182] and
Polyvinylchloride (PVC)[159].
The problem in using PVC for further study is from the initial fabrication process,
specifically with the organic solvent used during the fabrication process. A chance of
residual solvent causing unacceptable toxicities and a risk of side effect on target
animals limited the use of this material in clinical applications [183].
There are some common limitations of using non-degradable material to
synthesize a delivery system. Firstly, there is a high risk of inflammation during the
regeneration process, which may block the reconnection of neurons to proper targets.
Then the well maintained-structured scaffolds are more difficult for further
modification used for either cell attachment or biomolecule delivery. Implants
constructed of such non-degradable material also have a problem in that, for in vivo
studies, they need to be removed after treatment is complete. As a result it is more
suitable for a lifetime replacement in bone tissues than the spinal cord.
2.4.2.2 Degradable Materials
Degradable materials have played an important role in a number of tissue
49
engineering attempts. Synthesized degradable devices do not have to be removed with a
second surgery after the regeneration process is finished, and therefor perfectly meet the
demand of temporary presence of a scaffold in reparation. Mostly these materials came
from natural resources with porous rich structures providing potential space for
molecules or specific cell adhesion [184]. Most research also proved that degradation
products from biocompatible degradable materials that naturally exist in the human
body and can be flushed out by normal metabolic processes. As a result, there is less
chance for inflammation will occur [185]. In the study of SCI most of the
biodegradable materials used are either cross-linked polymers or co-polymers. Newly
regenerated tissue takes the space of the degraded polymer and rebuilds the connection
to achieve functional recovery after injury.
Using biodegradable material to fabricate scaffolds has some elements affecting
the selection of materials. From Table 2, we can see the advantages and disadvantages
for most biodegradable materials. Natural materials are easily harvested from resources
but come with complicated purification processes. Some highly cross-linked materials
have been integrated into other strategies. To enhance the mechanical strength, some
materials are modified with toxic agents. High water solubility also results in low
concentration in final material products, leading a fast degradation. For long-term repair
processes, a synthesized material with sufficiently long lasting mechanical properties,
desired degradation speed, and with the ability to accept therapeutic agents is an ideal
choice for device design.
50
The poly (glycolic acid)/poly (lactic acid)(PGA/PLA) family of compounds is a
member of the α-hydroxy acid class of compounds. This family includes poly (glycolic
acid)(PGA), poly (L-lactic acid)(PLLA), poly (lactic acid-co-glycolic acid)(PLGA),
poly (lactide-co-caprolactone)(PLCL), and poly (ε-caprolactone)(PCL). This family of
compounds has been found to have various degradation times, mechanical properties
based on different ratios of monomer units, stereochemistry of monomer units and
molecular weight distribution [159].
Material Advantages Disadvantages
Collagen Naturally exist in animal tissue.
Easy process integrate cell and
bimolecular treatment.[159]
Complicated purification
process.[186] Poor
mechanical
property.[187]
Chitosan Excellent biocompatibility and
easy harvest.
Degradation compressive
strength and cell attachment can
be controlled. [188]
Poor mechanical
property. [189]
Alginate/Ag
arose
Easily fill the cavity and low
immune response.[190]
Mitogenic and cytotoxic
impurity.[191]
51
Hyaluronic
Acid
Biocompatible,completely
degradable[192], and non-toxic.
[193]
High water solubility and
fast dispersesion.[194,
195]
Polyethylen
e glycol
Reduces the volume of cavity at
injury site.[196]
Low protein and cell
adhesion properties.[183]
Table 2 Advantages and disadvantages of using different biodegradable materials
Figure 9 Structure of Poly (lactic acid-co-glycolic acid)(PLGA)
PLGA, shown in Figure 9, is a commonly used material in drug delivery studies
and in the tissue engineering field. It has the properties of being biocompatible,
biodegradable, and (depending on the ratio of lactice to glcolide and molecular weight)
it has a wide range of degradation speed and mechanical properties. These properties
make it flexible for drug delivery device design [197]. Its decomposition products of
lactic acid and glycolic acid can easily metabolized by the human body, thereby it
minimizing systemic toxicity. PLGA has been used to make scaffolds seeded with
OO
H
O
HO
O
yx
poly(lactic-co-glycolic acid) (PLGA)
52
murine neural stem cells. Such scaffolds have been shown to provide an improvement
in functional recovery [198]. The ratio of lactic acid and glycolic acid affects the
degradation rate of the materials. Previous research has studied the physical properties
of materials created using the super critical carbon dioxide foaming method with lactic
acid to glycolic acid ratios of 85:15, 75:25, 65:35 and 50:50., It was found that
co-polymers with lower ratios of lactic acid to glycolic acid have smaller pores
and less porosity [199]. The PLGA degradation rate is directly related to the ratio of
lactic acid to glycolic acid. Lower ratios of lactic acid to glycolic acid enhance the
degradation rate of PLGA. Based on the same theory, PLGA degrade faster than PLLA
[200, 201].
Figure 10 Structures of Poly (L-lactic acid)(PLLA) and Poly (DL-lactic acid)(PLLA)
Poly (lactic acid) (PLA) based products are biocompatible materials and can be
degraded by hydrolysis. Based on the combination of the naturally occurring monomers
L-lactic and D-lactic can form three types of poly lactide: poly (L-lactide)(PLLA), poly
(D-lactide) (PDLA), and poly (DL-lactide) (PDLLA) [202]. In the human body, only
H O COH
CH3
HO
nH O C
O C
O
O
OHH
HCH3
CH3n
A B
poly-L-lactide acide (PLLA) poly-DL-lactide acide (PDLLA)
53
L-lactic is produced. For this reason, partially crystalline poly (L-lactic acid)(PLLA)
and amorphous poly (DL-lactic acid)(PDLLA) that degrade into L-lactic acid that
subsequently metabolizes into water and carbon dioxide are widely used in medical
fields. The structure of PPLA and PDLLA are shown in Figures 10A and 10B.
PDLLA and PLLA have different mechanical properties due to their different
crystallization. PLLA has better mechanical properties than PDLLA, which makes it
more commonly used in research fields [203]
Figure 11 structure of Poly (ε-caprolactone)(PCL)
PCL, shown in Figure 11 has been studied and exhibits outstanding mechanical
properties, flexibility, and biocompatibility [204]. Compared with PLGA and PLLA, it
degraded more slowly than PLLA, and has been more used for long-term scaffold
design [203]. PCL has a semi-crystalline structure with a lower glass transition
temperature (Tg) of -60 oC. At room temperature PCL exists in the rubbery state and has
better mechanical properties than other α-hydroxy acid compounds [205]. The slow
degradation speed of PCL makes it suitable for a long-term sustainable delivery [17].
Each member of the α-hydroxy acid class of compounds has its unique degradation
O
O
nPoly Caprolactone (PCL)
54
speed and mechanical properties. They have been used individually to fabricate
scaffolds for different reparation purposes but the potential of blending different
compounds together [206] or reorganizing the structures of integrated materials in
determined devices, means more varieties of different mechanical properties and
different degradation speeds.
2.4.3 Fabrication Techniques
Co-polymers used to deliver biomolecules can be synthesized through different
techniques into various forms and sizes. Stability and delivery speed of the same
biomolecule from the same material can be different based on various fabrication
techniques. To meet the requirements of specific device design, fabrication techniques
need to be involved during the initial design.
In scaffold design, pore size, porosity, and inter-connectivity strongly influence
cell growth and factors release profile [84]. Thus, a proper fabrication process is
required in scaffold design.
In Table 3 the advantages and disadvantages of different processes to synthesize
scaffolds are listed. Synthesized scaffolds working as implanted devices delivering
biomolecules need to maintain the bioactivity of the delivered molecules throughout the
whole treatment period. For this reason high temperature and solvent involved
processes, which may denature or reduce bioactivity of the biomolecules, cannot be
used.
55
Carbon dioxide, an important commercial and industrial solvent with advantages
of low toxicity, low cost, low processing temperature, high environmental impact, high
stability, and high solubility of most compounds, has been involved in different
polymer synthesized drug delivery systems in tissue engineering studies. After reaching
its critical temperature (304.25K) and critical pressure (72.9 atm), carbon dioxide turns
into a supercritical fluid with gaseous filling and liquid density. This supercritical fluid
can easily plasticize a wide range of polymers according to research studies [207].
Under this condition, polymers are plasticized, lowering their viscosity, and allowing
them to suspend insoluble particles [208].
Synthesize process Advantages Disadvantages
Electro Spinning Highly interconnected
scaffold
Organic solvent is
required[209]
Solvent Casting
Particulate Leaching
Simple handling
process and high
porosity
Poor morphologies and
organic solvent
required [31]
Emulsification
freeze-drying
Control over porosity
and pore size
Organic solvent is
required[210]
Liquid-Liquid phase
separation
Control over porosity
and pore size
Difficulty in
morphology
control[211]
56
CAD/CAM
Technology
Over control
architecture
High process
temperature, solvent
required[212]
Polymer melt process No organic solvent
process and control
over porosity
High Temperature
required [213]
Table 3 Advantages and disadvantages for various scaffold syntheses methods
Polymer and biomolecules are dissolved evenly in supercritical CO2 when
synthesizing a delivery device. Then the mixture expands, the polymer declines in
solubility and crystallization in that supercritical environment. Porous structured
scaffolds foamed by this process provide a template and guidance for cell growth. Pore
sizes can be controlled during the fabrication process. By adjusting the temperature, the
pressure, the molecular weight, and the chemical composition of polymers, scaffolds
with different porosities can be made[208]. This solvent free process elevates protein
activity for long-term release study [207].
In this research this solvent free process is used to create scaffolds that can release
two biomolecules according to the desired long-term release profile.
57
Chapter 3. Experimental
3.1 Materials
Polymers: Poly(DL-lactide-co-glycolide)with 50:50 monomer ratio (PLGA 50 :
50) easter terminated at an inherent viscosity range (I.V.) of 1.0-1.3 dL/g in CHCl3,
Poly (ε-caprolactone) easter terminated at an (I.V.) range of 1.0-1.3 dL/g in CHCl3,
Poly (L-lactide) easter terminated at an (I.V.) range of 0.9-1.2 dL/g in CHCl3, Poly
(DL-Lactide-co-ε-caprolactone) (80:20) initiated with 1-Dodecanol at an (I.V.)=0.85
dL/g in CHCl3 were purchased from Lactel Absorbable Polymers (Birmingham, AL,
USA).
Bioassays and biomolecules: Human FGF-basic Elisa Development Kit (EDK)
and Human EGF (EDK) were purchased from PeproTech, (Rocky Hill, NJ, USA). BCA
Protein Assay (linear working range of 5-250µg/mL) and Micro BCA Protein Assay Kit
(linear working range of 0.5-20µg/mL) were purchased from Pierce, (Rockford, IL,
USA). Albumin from bovine serum was purchased from Sigma, (St Louis, MO, USA).
Human FGF-basic growth factor and Human EGF growth factor were purchased from
PeproTech, (Rocky Hill, NJ, USA).
Chemicals: Sodium Azide was purchased from BDH Inc., (Toronto, ON, Canada).
Phosphate buffered saline tablet (pH 7.4) and Tween-20 were purchased from Sigma,
58
(St Louis, MO, USA). 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid), ABTS
substrate liquid was purchased from aMRESCO, (West Chester, PA, USA). Ethyl
Acetate was purchased from VWR International LLC, (West Chester, PA, USA).
Dichloromethane (DCM) was purchased from ACROS ORGANICS, (NJ, USA).
3.2 Scaffold Preparation
Scaffolds in this research were synthesized in two different steps. Microspheres
were synthesized first, and then integrated into tube shaped scaffolds based on the
different dissolvability of PLGA and PLLA/PCL in ethyl acetate.
3.2.1 Microsphere
Based on different requirements of tests, microspheres with different types of
molecules encapsulated were used to create different types of scaffolds.
3.2.1.1 Blank Microsphere
The fabrication of microspheres follows the oil-in-water (o/w) single emulsion
evaporation process. Dissolve 1000.00 mg of PLLA in 7.50 ml DCM at room
temperature. Add the mixed solution into 30.00 ml 1% (W/V) PVA (the internal
aqueous phase) with homogenizer (Brinkmann, NJ, USA) to get the emulsion mixture.
Add the emulsion mixture into 300.0 ml 0.1%(W/V) PVA (the internal aqueous phase)
and mechanically stir for 3 hours at 300 rmp until the DCM is evaporated. Centrifuge
59
the emulsion at 1000 rmp for 10 min and wash the microspheres collected at the bottom
5 times with dd-water. Freeze-dry and store the microspheres at -20 ℃ until they are
used in further experiments. The same process is used to prepare the PCL microspheres.
3.2.1.2 BSA Loaded Microsphere
Finely grind BSA powder with a mortar and pestle to obtain 100.00 mg of refined
BSA (lyophilized powder, ≥96%). Dissolve 1000.00 mg of PLLA in 7.50 ml DCM at
room temperature. Add the 100.00 mg of refined BSA into the mixture of PLLA and
DCM. (BSA: polymer / 1:10 in wt%). According to solubility table, BSA is suspended
in DCM solvent mixture. The s/o mixture needs to be kept stirring adding it into
30.00ml 1%(W/V) PVA (the internal aqueous phase). Follow the same procedure in
4.2.1.1 to prepare BSA loaded microspheres.
3.2.1.3 Growth Factor Loaded Microsphere
Before opening the bottle of growth factor, centrifuge it at 3000 rpm for 5 minutes.
Dilute 1 mg of EGF in 1.00 ml dd-water. Transfer the growth factor solution into a 50.0
ml volumetric flask with together with 1000.00 mg BSA and add dd-water to obtain
50.0 ml of solution. Freeze-dry the solution to get EGF-BSA mixed powder.
Finely grind EGF-BSA powder with a mortar and pestle to obtain 100.00 mg of
refined EGF-BSA. Dissolve 1000.00 mg of PLLA in 7.50 ml DCM at room
temperature. Add the 100.00 mg of refined EGF-BSA into the mixture of PLLA and
60
DCM. (EGF-BSA: polymer / 1:10 in wt%). According to solubility table, EGF-BSA is
suspended in DCM solvent mixture. Follow the same procedure in 4.2.1.1 to prepare
growth factor loaded microspheres.
3.2.2 Scaffold Tube
Dissolve 1000.00 mg PLGA in 10.00 ml ethyl acetate. Then add 1000.00 mg
prepared microspheres (the specific type of microspheres depends on the requirements
of specific tests). Using a mechanical stirrer mix the ethyl acetate PLGA and
microsphere mixture in a 40 ml beaker until a uniformly mixed. Pour the mixed
solution into a cylinder-shaped glass vial. As shown in Figure 12, dip a 3.00 mm
(diameter) glass rod into this mixed solution for 30 seconds, then pull out the glass and
using a drill rotate the rod at 300 rpm. Keep the glass rod in parallel position to the
ground and kept rotating for 30 minutes until the ethyl acetate completely evaporated.
While the glass rod is rotating, return the mixed solution to the 40 ml beaker and
continue stirring it. Repeatedly continue to transfer the mixed solution into the
cylinder-shaped glass vial to the same height, dip and rotate the glass rod, return the
mixed solution to the stirring beaker, until the desired diameter is achieved. (4.00 mm
for PLLA (MS)-PLGA scaffolds, 4.20 mm for PCL (MS)-PLGA scaffolds.) The
quantity of materials prepared is sufficient for six scaffolds of 30.00 mm in height.
After the dip-coating process, keep the glass rods under a 20 bar vacuum, for another 7
days ensure all the solvent is evaporated.
61
Figure 12 Dip-coating synthesized process
Place each dried sample into a Teflon mold and seal the top and bottom with
screws. Place all loaded mold into high-pressure chambers and foam with carbon
dioxide at 5.38 MPa (780psi). After 7 hours 30 seconds (saturation time 1-4 hours
according to reports [214]), release the pressure and keep the samples at room
temperature overnight (around 16 hours). Unload scaffolds from the molds, and then
remove the glass rods from the center of the scaffold. Keep all samples at -20 ℃ in the
freezer (according to polymers and growth factors storage condition) within a zip bag.
Before using for any test, allow the samples reach room temperature before open the zip
bag.
To prepare BSA or FGF-b loaded PLGA base tubes, add 100.00 mg BSA or
FGF-b and BSA mixture, depending on experiments requires, in the mixed solution
before the dip-coating process. For making growth factor FGF-b encapsulated tubes,
mix 40.00 mg of freeze-dried FGF-b-BSA mixed powder (prepared using the same
62
process as was used for the EGF growth factors in 4. 2. 1. 3) with 60.00 mg BSA
together (add up to 100 mg), then add it into the polymer solution.
3.3 In Vitro Release
Release studies of EGF growth factor, FGF-b growth factor, and BSA were done.
BSA is widely used in drug release studies to mimic the release behavior from delivery
systems, which has similar molecular weight and solubility as EGF and FGF-b. The
easy detection, long lasting stability, and less sensitivity to harsh environments
(specifically pH) together make it commonly used as a model for protein-based drugs in
release studies. The problem with using only BSA in this research is in order to
measure the release profile from two different parts of one scaffold, release behaviors
must perform by at least two tests. The differences in amount of BSA loaded on
different scaffolds through the fabrication process can affect the release profiles. In the
first test the BSA is impregnated into location one a scaffold, and the second test the
BSA in impregnated into a second location of a second scaffold, and the two release
profiles would have to be combined. To achieve release profiles from one scaffold
using different growth factors, on the other hand, can be detected separately by using
specific ELISA-kits in a complicated mixed solution. For this reason a single test can
be used to determine their separate release profiles, and which part of the scaffold they
came from. In this project, to confirm the final result, both growth factor release and
63
BSA release studies were done.
3.3.1 BSA Release
To validate the BSA release profiles from the different types of scaffolds, samples
are prepared following Table 4. The scaffolds must first be synthesized using the
previously described processes. To create the sample, in an individual microtube
(blocked with BSA) immerse 50.00±5.00 mg of each component shown in Table 4 is
immersed in 1000.0 µl PBS solution (with 0.1wt% sodium azide as a bacteriostatic
agent). All the samples were then incubated (Junior purchased from Isotemp, MA, USA)
at 37 ℃. Then 500.0 µl sample of each solution were extracted at day 1, 2, 4, 6, 8, 10,
12, 14, 18, 22, 26, 30, 34, 38, 42 and all the samples were kept in a freezer at -20 ℃
before being tested by BCA protein assay together with micro BCA protein assay. After
extracting a sample, each solution was topped up with 500.0 µl fresh PBS (with 0.1%
W/V sodium azide). All the required samples were collected in 42 days. Before
performing the BCA test, incubate all collected samples to 37 ℃.
Using a 96-well plate: for each sample, place 25.0 µl of the sample into 3 separate
wells. Then for each concentration of standard solution, place 25.0 µl of standard
solution into 3 separate wells. Then add 200.0 µl of mixed BCA-kit (reagent A: B / 50:
1) in each well. Incubate at 37 ℃ on a shaker at 100 rpm for 30 min. The concentration
of BSA in each well can be determined by color conversion and can be measured by
UV absorbance at 562 nm. The measurement is performed by using an Epoch plate
64
reader (BioTek, VT, USA).
When the concentration is below the detection limit of the BCA-kit (20 µg/ml) a
BCA-micro protein assay kit is used to measure the concentration. Using a 96-well
plate: for each sample, place 150.0 µl of the sample into 3 separate wells. Then for
each concentration of standard solution, place 150.0 µl of the concentration of standard
solution into 3 separate wells. Then add 150.0 µl of mixed BCA-micro protein assay kit
(Reagent A: Reagent B: Reagent C/ 25: 24: 1) in each well. Incubate at 37 ℃ on a
shaker at 100 rpm for 30 min. The concentration of BSA in each well can be
determined by color conversion and can be measured by UV absorbance at 562 nm. The
measurement is performed by using Epoch plate reader (BioTek, VT, USA).
Group
BSA location
1 2 3
PLLA
Microsphere
BSA / BSA
PLGA base / BSA BSA
Group
BSA location
① ② ③
65
PCL
Microsphere
BSA / BSA
PLGA base / BSA BSA
Table 4 Components in each group of scaffold in BSA release test
The concentrations of BSA, tested by either BCA-kit or BCA-micro kit, fit linear
Eq1.
C!! = a×Abs!! + 𝑏
Eq 1
Where
Abs!! stands for absorbance read at tn test point
C!! stands for concentration of BSA C!! at the point
a and b are equation parameters related to standard curve on each plate.
Quantity of protein can be calculated following Eq2
𝑚!! = C!!×𝑉
66
Eq 2
Where
m!! stands for amount of protein
V stands for volume of solution sample in each microtube in release study
Released protein samples at each pick up point can be detected by BCA-Kit or
BCA-micro protein assay kit. The absolute amount of protein released during the period
needs to be calculated. As per the procedure mentioned above, after extracting 500.0 µl
of each sample solution, top up each solution with 500.0 µl fresh PBS (with 0.1% W/V
sodium azide). Each time 500.0 µl of each sample solution is replaced with 500.0 µl
of fresh PBS, only half the mass (concentration) of the BSA remains in the sample
solution. The absolute amount of released BSA is calculated using Eq 3 when (n>1).
m!! +12m!!!! = m!!
Eq 3
Where
m!!stands for absolute amount of BSA released at point n
m!!!!stands for absolute amount of BSA released at point n− 1
m!!stands for detect amount of BSA released at test point n
67
When (n=1), use Eq 4.
m!! = m!!
Eq 4
By using the results of Equitation 3, (when n>1) Eq 5 is used to calculate the BSA
release profile over time from each scaffold.
𝑚!! = 𝑚!! +𝑚!!!!
Eq 5
Where
m!! stands for the accumulation of BSA released up to point n
m!!!!stands for the accumulation of BSA released up to point n− 1
At the first pick up time point (when n=1), accumulation of BSA released is the
same as detected amount of BSA, shown in Eq 6.
𝑚!!=m!!
Eq 6
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3.3.2 Growth Factor Release
For growth factors the release profiles were measured by using an enzyme-linked
immunosorbent assay (ELISA) test. ELISA test is a known technique used in
quantifying specific concentrations of determined target biomolecules in complex
solutions. The concentration of target biomolecule present is determined by color
conversion and can be measured by UV absorbance at 450nm with a correction at
650nm. To make sure the kit is designed to measure the growth factor used, the Human
FGF-basic (EDK) Elisa Development Kit and the Human EGF (EDK) Elisa
Development Kit should be purchased from the same company that supplied the EGF
and FGF-b growth factors. Each kit can quantifies only the amount of the respective
growth factor released from the synthesized scaffolds.
To create the sample, in an individual microtube (blocked with BSA) immerse
100.00±5.00 mg of each component shown in Table 5 into 1000.0 µl PBS solution
(with 0.1% W/V sodium azide as a bacteriostatic agent). All the samples are then
incubated at 37 °C. Extract 500.0 µl sample of each solution at day 1, 2, 4, 6, 8, 10, 12,
14, 18, 20, 24, 30, 36 and keep all the samples in a freezer at -20 °C until tested with
the appropriate ELISA-kit. After extracting a sample from each solution top up each
solution with 500.0 µl fresh PBS (with 0.1wt% sodium azide). It takes 36 days to
collect all the required samples. Before performing the ELISA-kit test, incubate all
collected samples to 37 °C.
69
Group
Materials
(1) (2)
Microsphere PLLA (EGF-BSA) 50%
Wt
PCL (EGF-BSA) 50%
Wt
PLGA base FGF-b (BSA) 50% Wt FGF-b (BSA) 50% Wt
Table 5 Components of each scaffold in growth factors release test
Dilute the concentration of the samples to the working range required by each
ELISA kit (EGF Elisa Development Kit with specific working range of 10-1000 pg/mL
and FGF-basic Elisa Development Kit with working range of 40-4000 pg/ml). By
following ELISA protocol (in attachment), the colored product can be found 5 minutes
after the ABTS substrate is added. The measurement is performed by using Epoch plate
reader (BioTek, VT, USA). Based on the standard samples on each plate, the
accumulation releases of the growth factors are calculated with equations 1-6.
70
3.4 Characterization of Scaffold
3.4.1 Scanning Electron Microscopy
Scanning Electron Microscopy (SEM) in this project was used to present
morphologies of all scaffolds. Structures and changing of morphology regarding to the
polymer degradation are shown in visualized pictures. All of the samples used in this
SEM characterization were synthesized following the process in 4.2 with components
of microspheres and PLGA base listed in Table 6.
Groups
Material
A B C
Microsphere PLLA (BSA)
50% Wt
PCL (BSA) 50%
Wt
/
Base PLGA (BSA)
50% Wt
PLGA (BSA)
50% Wt
PLGA (BSA)
100% Wt
Table 6 Components of each group of samples used by SEM and compressive test
Perpendicularly cut synthesized scaffolds into ring sections. Stick each ring shaped
sample onto a stub and test with Phenom Pro desktop SEM under 5kV
71
(PHENOMWORLD, Eindhoven, Netherlands)
3.4.2 Degradation Study
Degradation study on synthesized scaffolds is characterized by two parameters: the
changed structures (SEM) in 4.4.2.1 and the mass loss 4.4.2.2 of scaffolds over time.
3.4.2.1 Structure
Create 45 rings following the procedure in section 4.4.1, 15 (5 sets of 3) from each
of the groups/materials in Table 6. For each of the 45 rings, place them into an
individual microtube and add 1000.0 µl PBS solution to each microtube. Incubate all
the samples at 37 ℃. After (1, 2, 4, 6, 8, 10, 12, 14, 18, 20, 24, 30, 35, days) extract
500.0 µl of each solution from each microtube, and throw it away, and then top up each
microtube with 500.0 µl fresh PBS. In addition, each week remove 1 set of 3
microtubes from each of the groups/materials and wash the rings with dd-water, freeze
dry the microtubes with the rings, and keep them in a freezer at -20 ℃. It takes 5 weeks
to collect all the required samples. After the 5 weeks: before performing the SEM test
let the microtubes warm up to room temperature before opening the microtubes (to
avoid up take of moisture from the surrounding environment).
Stick each ring shaped sample onto a stub and test with Phenom Pro desktop
SEM under 5kV (PHENOMWORLD, Eindhoven, Netherlands) to obtain pictures of the
degradation of the ring material over time.
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3.4.2.2 Mass Loss
Degradation is a critical parameter for biodegradable materials, which affects the
drug release profile and the mechanical strength of the material over time. The in vitro
degradation of scaffolds is presented by mass loss based on Eq 7.
%𝑑𝑒𝑔𝑟𝑎𝑑𝑎𝑡𝑖𝑜𝑛 =𝑚 !"! −𝑚!"!𝑚!"! −𝑚!
Eq 7
Where
𝑚 !"!stands for the initial weight of scaffold and the tube
𝑚!"!stands for weight of scaffold and tube at week n
𝑚! stands for weight of tube
Groups
Material
a b c
Microsphere PLLA (50%
Wt)
PCL (50% Wt) /
PLGA base PLGA (50% PLGA (50% PLGA (100%
73
Wt) Wt) Wt)
Table 7 Components of each group of samples used in mass loss study
Following the Table 7, create 54 sample scaffolds, 18 (6 sets of 3) from each of the
groups/materials, so each tube weighs 60.00±3.00 mg. For each of the 54 sample
scaffolds: weigh a microtube used as 𝑚! , then place a sample scaffold into the
microtube and weigh the microtube again to figure out the weight of the sample
scaffold in the microtube. Record this value and use is as 𝑚!"! to be used in Eq 7 for
this sample scaffold. Then add 1000.0 µl PBS solution to each of the microtubes.
Incubate all the samples at 37 ℃. After (1, 2, 4, 6, 8, 10, 12, 14, 18, 20, 24, 30, 36, 42
days) extract 500.0 µl of each solution from each microtube, and throw it away and then
top up each microtube with 500.0 µl fresh PBS. In addition, each week remove 1 set of
3 microtubes from each of the groups/materials and wash the sample scaffolds with
dd-water, and freeze dry the sample scaffolds in their microtubes for 2 days. Then
weigh the microtube containing the sample scaffold and compare this result with the
weight of this microtube recorded at the beginning of the test to determine the mass of
sample scaffold lost over time. Use this value as 𝑚!"! in Eq 7 for this sample scaffold.
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3.4.3 Mechanical Testing
Mechanical testing is one of the required design parameters for this study to
enhance scaffolds’ performance and to meet demands of native tissue with sufficient
mechanical integrity. For material in compressive test, there is a linear region following
Hooke’s Law and presents by Young's modulus shown in Eq 8.
𝐸 =𝑐𝑜𝑚𝑝𝑟𝑒𝑠𝑠𝑖𝑣𝑒 𝑠𝑡𝑟𝑒𝑠𝑠𝑐𝑜𝑚𝑝𝑟𝑒𝑠𝑠𝑖𝑣𝑒 𝑠𝑡𝑟𝑎𝑖𝑛 =
𝜎𝜀 =
𝐹𝐴!𝛥𝐿𝐿!
=𝐹𝐿!𝐴!𝛥𝐿
=𝐹𝐿!
𝜋(𝐷2)! − 𝜋(𝐷2 − 𝑑)
! 𝛥𝐿
Eq 8
Where
E stands for Young's modulus (modulus of elasticity)
F stands for the force exerted on an object under tension;
A0 stands for the original cross-sectional area through which the force is applied;
ΔL stands for the amount by which the length of the object changes;
L0 stands for the original length of the object;
D stands for the outer diameter of the object;
d stands for the wall thickness of the object.
75
Following the Table 6 create 54 sample scaffolds, 18 (6 sets of 3) from each of the
groups/materials so each tube is 5.00±0.02 mm (length± standard deviation) long, and
smooth both ends of the sample scaffold with sandpaper so the ends are square.
Measure the length of all the scaffolds 5 times, and make sure the length of all the
sample scaffolds are within 0.01mm. Then put each of the 54 scaffolds into separate
microtube and add 1000.0 µl PBS solution (with 0.1% W/V sodium azide) to each of
the microtube. All the samples are then incubated at 37 ℃. After (1, 2, 4, 6, 8, 10, 12,
14, 18, 20, 24, 30, 35 days) extract 500.0 µl of each solution from each microtube, and
throw it away and then top up each microtube with 500.0 µl fresh PBS (with 0.1% W/V
sodium azide). In addition, each week remove 1 set of 3 microtubes from each of the
groups/materials and wash the sample scaffolds with dd-water. For each of the 3 tube:
measure the outer diameter, the inner diameter and the length of the scaffold with
vernier calipers 5 times, and make sure the value of all the same measurements are
within 0.01mm difference. These values are entered into the compression tester
(purchased from Instron, Canton, MA) and are used as parameters in Eq 8. Place each
tube in-between compression platen of the compression tester and adjust the platen so
they are just touching both ends of the scaffold. The compression tester is then set with
250N load cell and 0.2 in extensional strain. The compression tester measures the
extensional stress and the compressive strain and reports Young's modulus. Results are
exported with automatic modulus and raw data in tensile stress and strain. Plots in
modulus regarding to time graph shows changing of mechanical property.
76
Chapter 4 Results and Discussions
4.1 Release Study
Results of release studies of EGF growth factors, FGF-b growth factor, and BSA
are shown in Figures 13 to 16.
In the BSA release study, BSA is the only molecule encapsulated in the
microspheres, PLGA base, or both. The same polymer components and procedures
were used to synthesize PLLA microsphere (MS)-PLGA scaffolds or PCL (MS)
microsphere-PLGA scaffolds with BSA encapsulated at different locations. In each
type of scaffold, the BSA released from microspheres, PLGA base and microspheres
with PLGA base are presented in the same graph.
In the growth factor release studies, both EGF and FGF-b are released from the
same scaffold for example PLLA microsphere in PLGA scaffold or PCL microsphere in
PLGA scaffold. The released growth factors for the scaffold are presented on one
graph.
4.1.1 BSA Release Studies
BSA released from PCL (MS)-PLGA scaffolds and PLLA (MS)-PLGA scaffolds
are shown in Figure 13 and Figure 14. BSA encapsulated in both PLLA and PCL
microspheres gradually released in 42 days, but in PLGA base, BSA has an initial
77
release in 6 days, followed by steady stage with no release in the rest of the test. The
PCL (BSA)-PLGA (BSA) scaffold plot is for BSA encapsulated in both microspheres
and the PLGA base of the scaffold. As the BSA is gradually released from the
microspheres, the release profile soon catch up with that of BSA released from the
PCL-PLGA (BSA) scaffold, which only has BSA just encapsulated in PLGA base. The
quantity of BSA released versus time is presented in units (µg BSA/ mg sample) versus
days.
Results of BSA released from PCL (BSA)-PLGA scaffolds are shown in 13. The
BSA in the microspheres has 1.36 µg /mg (42.57%) of BSA released in the first 4 days;
an additional 1.84 µg /mg is released from day 4 to day 42. For the PCL-PLGA (BSA)
scaffold with BSA localized in PLGA base, 12.83 µg /mg of BSA (85.82%) is released
in the initial 6 days and a small quantity of 2.13 µg /mg of BSA is released in a long
period of 33 days from day 7 to day 42. Compared with the quantity of BSA released at
the initial time, it has almost no BSA releases in the following stage. The BSA released
from the PCL (BSA)-PLGA (BSA) scaffold confirms the release behavior has both the
initial release rate of the PCL-PLGA (BSA) scaffold and the long-term release rate of
the PCL (BSA)-PLGA scaffold.
78
Figure 13 In vitro release studies of BSA release from PCL (MS)-PLGA (base) scaffold in 42 days.
Results of BSA released from PLLA (MS)-PLGA scaffolds are shown in Figure
14. The BSA in the microspheres has 2.05 µg /mg (44.28%) of BSA released in first 4
days; an additional 2.58 µg/mg released from day 4 to day 42. For the scaffold with
BSA localized in the PLGA base, 16.03µg/mg of BSA (95.02%) is released in the
initial 6 days and a small quantity (0.84µg) of BSA released in a long period of 33 days
from day 7 to day 42. Compared with the quantity of BSA released at the initial time, it
has almost no BSA releases in the following stage. The BSA released from the PLLA
(BSA)-PLGA (BSA) scaffold confirms the release behavior has both the initial release
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50
Accu
mula%
on (μ
g/mg)
Days
PCL (MS)-‐PLGA (base)
PCL(BSA)-‐PLGA
PCL-‐PLGA(BSA)
PCL(BSA)-‐PLGA(BSA)
79
rate of the PLLA-PLGA (BSA) scaffold and the long-term release rate of the PLLA
(BSA)-PLGA scaffold.
Figure 14 In vitro release studies of BSA release from PLLA (MS)-PLGA (base) scaffold in 42 days.
Theoretically speaking, when BSA is loaded on both microsphere (PLLA/PCL)
and PLGA base of one scaffold, the release profiles should go over that of the
scaffold with BSA loaded on PLGA base only. Unfortunately, the scaffolds are not
synthesized at the same time. The uncontrollable conditions, for example, the
differences in batch reaction and the BSA lost during supercritical CO2 foaming
process together affect the total amount of BSA loaded in each scaffold. A test that
can preform release profiles form different parts of one scaffold could minimize
the differences caused by the uncontrollable situation stated above. Therefore to
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50
Acum
ulation (μg/mg )
Days
PLLA (MS)-‐PLGA (base)
PLLA(BSA)-‐PLGA
PLLA-‐PLGA(BSA)
PLLA(BSA)-‐PLGA(BSA)
80
confirm the BSA release results, growth factor test was performed.
4.1.2 Growth Factors Release Studies
Released growth factors from PCL (MS EGF)-PLGA (FGF-b) scaffolds and PLLA
(MS EGF)-PLGA (FGF-b) scaffolds are shown in Figure 15 and Figure 16. EGF
encapsulated in both PLLA and PCL microspheres has a small initial release and is
followed by a continual release up to 36 days. In PLGA base, FGF-b has an initial
release in 8 days, followed by steady stage with no release in the rest of the test. The
quantity of growth factor released versus time is presented by (pg growth factor/ mg
sample) versus days.
In the PCL (MS EGF)-PLGA (FGF-b) scaffold release study shown in Figure 15,
EGF encapsulated in PCL microspheres, 396.22 pg/mg of EGF is released in first four
days followed by 162.05 pg/mg EGF a sustained release from day 4 to day 36 due to
degradation and erosion of PCL microsphere. For FGF-b localized in PLGA base,
963.46 pg/mg (95.43%) is released in the initial 8 days. From day 8 to day 36, FGF-b
release finished with a total amount of 1009.50 pg/mg.
81
Figure 15 In vitro release studies of EGF and FGF-b from PCL (MS)-PLGA scaffold in36 days.
In the PLLA (MS EGF)-PLGA (FGF-b) scaffold release study shown in Figure 16,
In EGF encapsulated PCL microspheres, 321.27 pg/mg of EGF is released in the first 4
days. From day 4 to 36 and additional 165.45 pg/mg EGF is released due to degradation
and erosion of PLLA microsphere. For FGF-b localized in PLGA base, 720.09 pg/mg
(91.65 %) is released in the initial 8 days. From day 8 to day 36, FGF-b release finished
with a total amount of 785.74 pg/mg.
0 100 200 300 400 500 600 700 800 900 1000 1100
0 10 20 30 40
Accumulation(pg/m
g)
Days
PCL (MS)-‐PLGA (base)
FGF-‐b(PLGA-‐base)
EGF(PCL-‐MS)
82
Figure 16 In vitro release studies of EGF and FGF-b from PLLA (MS)-PLGA scaffold in 36 days.
Similar release behaviors of release from PLGA base and PLLA/PCL
microspheres have been shown in both BSA and Growth factors EGF and FGF-b
release studies.
4.1.3 Sequential Release Approach
Releasing more than one growth factor sequentially requires controlling when the
growth factors are released and the sequence that the growth factors released in.
Sequential release can be achieved by accelerating the release of the first molecule and
by delaying the release of the second one. The sequence of the growth factors released
from the system is generally determined by the reverse sequence of growth factors built
0 100 200 300 400 500 600 700 800 900 1000 1100
0 5 10 15 20 25 30 35 40
Accumulation(pg/m
g)
Days
PLLA (MS)-‐PLGA (base)
FGF-‐b(PLGA-‐base)
EGF(PLLA-‐MS)
83
into the release system.
4.1.3.1 First Release Approach
The initial burst is assigned to the leaching of molecules through the porous
surface of polymer microspheres [215]. Therefore initial release is greatly affected by
porosity and pore size. Increasing either parameter of the delivery vehicle may lead to a
quick molecule release rate [216]. Based on this idea highly porous hydrogels, for
example hyaluronanmethylcellulose, and alginate [154-156] are commonly used as the
first release material. Similar to the hydrogels, PLGA scaffolds foamed by supercritical
CO2 have high porosity as well as large pore sizes. The release starts immediately and
then finishes in a relatively short time. In a similar study, FGF-b was released from a
PLGA scaffold foamed by supercritical CO2 process. The FGF-b exhibited a great
initial burst release, and the release was completed in seven days [217],which is
similar to the results obtained in this research. Both BSA release profiles (in Figure 13
and 14) and growth factor FGF-b release profiles (in Figure 15 and 16) show the release
from PLGA based scaffold was completed in 7 days. These results demonstrate the
ability of PLGA based scaffolds to achieve a fast first release of FGF-b. Scaffolds
synthesized from PLGA have higher release control and mechanical strength than
scaffolds made of gels, but it is hard to incorporate another molecule to be released at
different time.
84
4.1.3.2 Second Release Control
Molecule release kinetics from polymetric microspheres is affected by polymer
erosion, dissolution, and diffusion [218-220] and can be used to create a second drug
release phase [200]. As shown in Figure 13 and Figure 14, the release of BSA from
microspheres has a steady second release period starting after day 4 and a similar result
has been found for EGF released from scaffolds with the same structure (release
profiles shown in Figure 15 and 16). This second release phase from microspheres
proves the designed scaffolds have the possibility to release a different growth factor in
a controlled and delayed manner. By taking advantage of this characteristic of delaying
and extending the second release stage, the designed scaffolds have the ability to
release two growth factors in different periods. In the initial design, there are several
critical parameters involved to achieve this goal.
The crystalline of different polymers is used in the designed scaffold to manipulate
the release profile. PLLA and PCL have higher crystalline than that of PLGA, which
provides the materials with a slower degradation rate and lower solubility in
supercritical CO2 [19, 221]. Therefor, material wise, the degradation related release
from both PLLA and PCL microspheres is slower than that from a PLGA base. The
lower solubility of PLLA and PCL in CO2 makes it possible to create microspheres
with a smoother surface than the sponge structured PLGA base shown in SEM pictures
in Figure 17. This results in reduced porosity and pore size, which also contributes to
85
slowing down the release rate. Both of the effects make PLLA and PCL microspheres
promising candidates for the second sustainable growth factor delivery vehicle.
4.1.4 BSA Release Versus Growth Factors Release
Both the BSA release study and the growth factor release studies establish the
same trends for release kinetics from microspheres or PLGA based tube. Compared
with the BSA release study, initial EGF released from both PLLA (MS)-PLGA
(66.00%) and PCL (MS)-PLGA (70.97%) scaffolds at day 4 are higher than that found
in BSA released from PLLA (MS)-PLGA (44.28%) and PCL (MS)-PLGA (42.57%).
These differences may be caused by the bioactivity of growth factors used in long-term
in vitro release studies [130]. Research using different encapsulated molecules obtains
different release profiles, but the release trends were similar [138]. BSA can maintain
its bioactivity in harsh environments, which makes it very popular for use as a release
model in most studies [222]. After the initial burst, BSA and growth factors gradually
release of the remaining 35 to 60% of the protein encapsulated in the microspheres
integrated into these scaffolds.
4.1.5 Encapsulation Efficiency in Growth Factor Release
The encapsulation efficiency of biomolecules in microspheres is less than that in
PLGA base. In growth factors release study, EGF is released more slowly from
microspheres than that of FGF-b from PLGA base. In BSA release study, BSA is
86
released more slowly from microspheres than from the PLGA base. Encapsulation
efficiency of biomolecules in microspheres is 20.4 ± 4.8 % through single emulsion
synthesize process and 83.1 ± 3.5% for dip coating process. Data has been collected by
pre-research studies and been calculated among five samples. BSA and FGF-b have
higher efficiency to be encapsulated in PLGA than BSA and EGF in PCL or PLLA
microspheres. Consequently, higher quantity of accumulation is obtained for studies of
release from PLGA than microspheres.
Similar performance was observed in PLLA (MS)-PLGA and PCL (MS)-PLGA
scaffolds. Due to their dissolubility in ethyl acetate, PLLA microspheres encapsulate
biomolecules better than PCL microspheres, however, PCL degrades more slowly than
PLLA and creates a more uniform structure for PCL (MS)-PLGA scaffolds. For these
reasons, both exhibit a good sustained slow second release, which may provide a
promising guidance to related cell behaviors.
4.2 Scanning Electron Microscopy
In this study, SEM is used to characterize the morphologies of sections from
scaffolds in different compositions. The results present a general view of scaffolds as
well as detailed images of pore size and microsphere distributions.
87
In Figure 17, an overview of scan images of scaffolds is shown in A, C, E with a
200µm scale bar with structure details shown in B, D, F with an 80µm in the scale bar.
The overview images show one fifth of each ring shaped scaffold, and indicate the
location of the corresponding detailed picture. The detail images are chosen from
marked areas for general geometry observation.
The PLGA scaffold in Figure 17 A and B has macro pore sizes in the range of
50-200µm, uniformly distributed inside tubes. These pores easily uptake water and
leach away hydrophilic biomolecule loading from the material with diffusion effect.
This sponge structured tube also creates space to provide the scaffold with loading
capability.
The PLLA (MS)-PLGA scaffold shown in C and D are more uniform with smaller
pore size distribution. The detailed picture D also shows the microspheres evenly
distributed embedded in the PLGA based tube. Sizes of microspheres are in a limited
range of size distribution of 15-20µm. The microspheres of certain size can easily fit in
the high porosity PLGA base. With 50 wt% of PLLA microspheres in PLGA scaffolds
(C and D) and 50 wt% of PCL microspheres in PLGA scaffolds (E and F), PLGA is not
be able to keep its original shape, the PLGA is pushed to go around non-foamed PLLA
microsphere and stuffs the space in-between microspheres, working like glue to connect
particles together. In the dip-coating fabrication process, microspheres are evenly
distributed in scaffolds. In Figure 17-D some of the microspheres are cut in half by
chance. Inside the microsphere, a solid encapsulated structured core can be seen
88
confirming the biomolecule loaded microsphere syntheses process. Polymer shell for
microspheres is made of PLLA, which is not foamed in supercritical CO2, resulting in a
more solid and high density surface with a less porous structure. Compared with
sponged structure PLGA, PLLA microspheres then provide better structure to delay the
biomolecule diffusion. The longer it takes for the biomolecule to travel from the
microsphere makes it possible to provide a time difference for biomolecule released
from PLGA base and PLLA microspheres.
Images E and F show sections of PCL (MS)-PLGA scaffolds. Different from the
first two scaffolds, they have a smoother surface with fewer pores with a maximum
pore diameter of 50µm. Due to being partially dissolved PCL in ethyl acetate, the
dissolved PCL together with the PLGA is well mixed and covers all the integrated
microspheres. As a result, microspheres are not shown well on sections in PCL
(MS)-PLGA scaffolds. The dissolved PCL in ethyl acetate also changes the PLGA
porous structure after supercritical carbon dioxide foam. The more solid structure with
fewer pores provides it with different characteristics than in other studies.
89
Figure 17 SEM images of PLGA in A, B; PLLA (MS)-PLGA in C, D ; PCL (MS)-PLGA in E, F ; different
90
magnifications A, C, E with a scale bar of 300 µm and B, D, E with a scale bar of 80 µm
4.3 In Vitro Degradation Study
The degradation of PLGA, PLLA (MS)-PLGA, and PCL (MS) -PLGA scaffolds is
shown in both the mass loss profile in Figure 18 and in the morphology structure
changes over time as shown in the SEM images in Figure 19. To highlight the
degradation of just the polymers no biomolecule has been encapsulated in either
microspheres or PLGA base.
4.3.1 Mass Loss
Figure 18 shows, mass loss for all scaffolds is low for the first three weeks. Mass
loss of PLGA scaffolds starts to accelerate right after the third week, PLLA
(MS)-PLGA scaffolds start to loss their weight after the fourth week, and PCL
(MS)-PLGA scaffolds start after the fifth week. PCL starts more slowly than PLLA,
and PLLA degrades more slowly than PLGA.
Shown in Figure 18, up to week 3, 5.93 ± 0.01 % of PLGA scaffolds degraded, 4.5
± 0.01 % of PLLA (MS)-PLGA degraded, and 2.63 ± 0.003 % of PCL (MS)-PLGA
degraded. Accelerated degradation of PLGA starts after week 3, 23.97 ± 0.05%
degraded up to week 4, 42.9 ± 0.05% up to week 5, and 58.26 ± 0.06% up to week 6.
Compared with PLGA scaffolds degradation accelerates on PLLA (MS)-PLGA
91
scaffolds from week 4 and 11.5 ±0.01% degraded up to week 5, followed by 23.27 ±
0.02 % up to week 6. PCL (MS)-PLGA scaffolds’ degradation accelerates one week
after PLLA (MS)-PLGA scaffolds. Up to week 69.57 ± 0.01 % of scaffold degraded.
In each testing point, newly designed scaffolds degrade slower than PLGA
scaffold. Compared between PCL (MS)-PLGA scaffold and PLLA (MS)-PLGA
scaffold, PCL (MS)-PLGA scaffold degrade slower than PLLA (MS)-PLGA scaffold.
Figure 18 Percentage of mass loss for in vitro degradation study of PLGA, PLLA (MS)-PLGA, and PCL
(MS)-PLGA scaffolds in 6 weeks.
Based on mass loss, bulk polymer degradation consists of two stages. In the first
stage, the degradation of bulk-degrade polymer backbones hydrolyzed over time into
92
smaller chains [200], then over time these chains break down into smaller chains. This
is reflected in the mass loss result in Figure 18 during week 1 to week 3, in that no
sharp mass loss occurs during this period. In the second stage, small fragments can be
further hydrolyzed [200] and when the molar mass of fragments goes down to 100
g/mol [223], hydrolysis products can dissolve in water creating an accelerated mass loss.
For PLGA and PLLA a second sharp mass loss stage can be observed in their
degradation profiles. Due to the slow degradation characteristic of PCL, its degradation
profile is not visible in the 5 week test conducted in this research project, but other
research has shown that PCL mass loss starts after approximately 10 weeks [224]. This
result is shown by the rate of scaffold degradation over time in Figure 18. PLGA
scaffolds exhibit significant mass loss one week earlier than PLLA (MS)-PLGA
scaffolds, and two weeks earlier than PCL (MS)-PLGA scaffolds.
4.3.2 SEM Image Analysis
In Figure 19, PLGA scaffolds, PLLA (MS) -PLGA (50/50wt%) scaffolds, and
PCL (MS)-PLGA (50/50 wt%) scaffolds morphologies have been scanned by SEM on
week 1, 3 and 5. The surfaces for all the scaffolds are getting rough as well as the
structures are getting loose and weak over time
The morphology changes in PLGA scaffolds are shown in images a, b, and c
indicating the changed structures of scaffolds in week 1, 3 and 5. The section cut
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samples from scaffolds get rough on the surface over time. The small pores, with
diameter around 60-100µm in week 1, can be found in week 3. In week 5, the whole
structure of the PLGA scaffold is broken into small pieces. After five weeks, taking
mass loss data into consideration; 58.27% of material degraded, the rest of the PLGA is
no longer able to hold the structure. Due to the weak structure of degraded scaffold,
they collapse during the freeze-drying process and cannot be made into SEM samples
after five weeks.
The morphology changes on PLLA (MS)-PLGA scaffolds are shown in images d,
e, and f indicating the changed structures of scaffolds in week 1, 3 and 5. After the first
week of degradation, microspheres are slightly shown better compared with Figure 17
D. On week t 3, as shown in the Figure 19 e, surface is rougher, but the porosity didn’t
change a lot. On week five, most of the PLGA base is degraded, the pore size has
increased greatly, and similar result in an increased mass loss shown in Figure 18. The
porosity in week compared with first week has increased, but the pore size didn’t
change a lot. In week 5, the pore size greatly increased due to degradation of scaffold
and the number of microspheres is reduced.
The morphology changes on PCL (MS)-PLGA scaffolds are shown in images g, h,
and i, indicating the changed structures of the scaffolds in week 1, 3 and 5. Compare
among the pictures, the fist week has fewer pores than week 3, but the pore size stays
the same. In week five, the morphology of the scaffold greatly changed. Due to partially
dissolved PCL in ethyl acetate, however, at week three, microspheres could be found in
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the pores, together with increased surface roughness. In week five, more not perfect
sphere particles are seen, and more roughed surfaces can be found compared with
images in week 1 and 3.
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Figure 19 SEM images of PLGA scaffolds in week 1 a, 3 b, 5 c; PLLA (MS)-PLGA scaffolds in week 1 d,
3 e, 5 f ; PCL (MS)-PLGA scaffolds in week 1 g, 3 h, 5 i. All images are under the same magnification
with a scale bar of 80 µm
Recent practical research studies indicate there is no significant correlation
between the hydrolysis products catalytic reaction and scaffold degradation [225].
Therefor, scaffolds having high porosity and large pore size lead to high degradation
rates [226]. The mass loss related degradation is strongly influenced by initial scaffold
structure design in this project. This is demonstrated in the SEM images in Figures 17
D, and F, where the pore size is decreased and a uniform structure is created. Due to the
different solubility of PLLA and PCL microspheres in ethyl acetate, the cross-sectional
area remains more intact than for the PLGA scaffold showed in Figure 17 B. The
designed PLLA (MS)-PLGA and PCL (MS)-PLGA scaffolds contain equal masses of
microspheres and PLGA. Theoretically speaking, these newly designed scaffolds
should degrade at half the rate of pure PLGA scaffolds. This is borne out by the results
shown in Figure 18 showing that most of the scaffolds lose less than half as much mass
as the pure PLGA scaffolds. The microspheres in PLGA tubes reduce the porosity and
the pore size consequently reduced the degradation rate of the scaffolds. Compared with
PLLA (MS)-PLGA scaffolds, PCL (MS)-PLGA scaffolds have lower porosity and pore
size and degrade more slowly than PLLA (MS)-PLGA scaffolds. The delayed onset of
mass loss is due to their structure and the characteristics of PLLA and PCL. Thus the
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newly designed scaffolds should sustain longer in vivo, meeting the need of long-term
reparation.
In Figure 19, the pore size and porosity change in a and b, d and e, g and h are not
significant in the first three weeks, and the same trend can be found in mass loss plot in
Figure 18. In the first three weeks, mass loss stays within less than 5%. In the fifth
week, both pore size and porosity in Figure 19 c, f, and i, are increased, and in f and i
the microspheres are easily visible. In Figure 18, consequently mass loss decreases
sharply over time.
4.3.3 Structure Change in Mass Loss Studies
Comparing the two newly designed scaffolds, the PLLA (MS)-PLGA scaffold
exhibits faster mass loss than the PCL (MS)-PLGA scaffold. This may be caused by
microsphere loss during degradation. A follow up study has been done on the designed
scaffolds by incubating them for up to 6 months. In this time the PLGA scaffolds are
totally degraded. In the same time the PLLA (MS)-PLGA scaffolds is still visible and
particles are visible in the bottom of micro-tubes, but the scaffolds collapse when
shaken. Meanwhile, the PCL (MS)-PLGA scaffolds hardly have any particles in the
bottom of the microtubes, but the wall thickness has decreased. According to these
observations, the mass loss of the scaffolds may be caused by microsphere leaching. In
the case of the PLGA base containing the PCL MS, the PCL partly dissolves into the
base. As a result, the PLGA/PCL base degrades more slowly, thus the MS are lost more
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slowly. In comparison the PLGA base containing the PLLA MS degrades more quickly
resulting in the more loss of its MS, which equates to higher mass loss.
4.4 Compressive Test
The compressive strength was tested on PLGA scaffolds, PCL (MS)-PLGA
scaffolds and PLLA (MS)-PLGA scaffolds. Young’s Modulus ± standard deviation
regarding the degradation over time in each type of scaffolds is shown in Figure 20
According to the physical properties provided by manufacturer, the modulus of
PLGA (50:50) is 1.38-2.76×106 MPa [227]. Scaffolds synthesized by different
techniques, with different synthesized conditions and different materials make
scaffolds with different mechanical strength. Specifically produced by supercritical
carbon dioxide, the mechanical properties of scaffolds are affected by molecule weight,
chemical composition, temperature, pressure, and foaming time [199, 228]. PLGA
hollow fiber membrane has an modulus of 109 MPa [229].
In this research PLGA scaffolds have an initial modulus of 151.15 ± 0.30 MPa,
while PLLA (MS)-PLGA scaffolds have an initial modulus of 205.31 ± 10.43 MPa,
and PCL (MS)-PLGA scaffolds have a modulus of 260.42 ± 12.35 MPa. The
mechanical property of both the PLLA (MS)-PLGA and the PCL (MS)-PLGA scaffolds
have been improved compared to pure PLGA scaffolds.
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After the first week of degradation, PLGA scaffolds lost half of their mechanical
properties and go down to 73.26 ± 18.90 MPa, however, both PLLA (MS)-PLGA and
PCL (MS)-PLGA scaffolds keep their modulus at 202.47 ± 41.68 MPa and 237.03 ±
20.77 MPa. During the second week, mechanical properties for both PLGA and PLLA
(MS)-PLGA scaffolds start to go down to 59.45 ± 4.62 MPa and 179.85 ± 9.25 MPa.
PCL (MS)-PLGA scaffolds keep their mechanical properties until week three. A
slightly decreased modulus of 11.95 MPa happened at this period.
In week four, the modulus of PLGA scaffolds goes down to 1.48 ± 0.81 MPa and
basically loose their mechanical properties. For PLLA (MS)-PLGA and PCL
(MS)-PLGA still keep 95.68 ± 3.82 MPa and 136.04 ± 17.94 MPa of their original
mechanical properties. In week five, the modulus of PLLA (MS)-PLGA scaffolds is
60.03 ± 24.36 MPa, compared to the modulus of PCL (MS)-PLGA scaffolds, which is
68.95 ± 12.20 MPa. Both newly designed scaffolds, PLLA (MS)-PLGA and PCL
(MS)-PLGA, preform better at the fifth week than PLGA scaffolds at the second week
with modulus of 59.45 ± 4.62 MPa through compressive test.
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Figure 20 Young’s Modulus for PLGA, PLLA (MS)-PLGA, PCL (MS)-PLGA scaffolds over time.
4.4.1Mechanical Properties of Scaffolds
From a typical compressive stress-strain curve, there are three regions exhibited
during the test: the linear elasticity at low stresses region, where compressive stress
rises with the strain; the long collapse plateau region, where scaffold cells collapse; and
the densification region, where continued application of force on the already collapsed
sample increases the stress [230]. As shown in Figure 21, for example, the test of
PLGA scaffold fits the three regions in stress-strain graph. To be usable for SCI studies,
the mechanical strength of the scaffold needs to be strong enough to prevent collapsing.
The mechanical strength of each scaffold is determined by calculating the slope of the
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initial linear region in each of its stress versus strain graph. A similar technique to test
mechanical strength has been performed in other studies, for example, in PCL-PLGA
blended scaffold [231] and poly(2-hydroxyethyl methacrylate-co-methyl methacrylate)
hydrogel tubes [232].
Figure 21 Compression stress-strain curve of PLGA scaffold.
Scaffolds utilized for tissue engineering are required to reach appropriate
mechanical properties. The optimum value is dependent on the target tissue, and a
minimum value of 0.1 MPa is required for ultimate tissue or organ formation [233].
Scaffolds used for in vitro studies may degrade faster than those used for in vivo studies
[224]. Thus, scaffolds having high initial mechanical strength and long lasting
mechanical strength are required for in vivo studies.
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Blending PLGA with various materials has been studied in other research and has
been shown to improve the modulus of single PLGA. For instance PLGA scaffolds
blended with poly (ethyleneoxide)- poly (propyleneoxide)- poly (ethyleneoxide) has an
initial modulus of 160 MPa [234], and PLGA (50:50) mixed with different percentage
of NaCl and TCP have a range of modulus from 54±17 to 450±79 MPa [235].
In other research PLLA has been made into various structured scaffolds with
initial modulus from 85.80 ± 37.70 to 642.26 ± 161.54 [225] respectively on various
structures, which are higher than PLGA. The mechanical strength of PLLA also
decreases more slowly than PLGA [236]. PCL scaffolds remain 20% of the original
mechanical strength after 70 weeks [237], which also decrease more slowly than PLGA
scaffolds. Scaffolds created by integrating PLLA or PCL can elevate the mechanical
strength of PLGA scaffolds. Therefor in the comprehensive test, designed scaffolds
have high mechanical strength than PLGA scaffold in any testing point.
For the scaffolds synthesized in this project, the PLLA (MS)-PLGA scaffolds have
an initial modulus of 205.31 ± 10.43 MPa, and the PCL (MS)-PLGA scaffolds have a
modulus of 260.42 ± 12.35 MP. Both of the moduli are in a regular range for PLGA
based blended scaffolds.
4.4.2 Structure Change in Mechanical Testing
The modulus and tensile strength also affected by the cross-sectional area.
Increased porosity and pore size decrease the estimated of cross-sectional area under
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stress [238]. As a result, less porous scaffolds have a higher modulus [225]. The
detailed structures of the tubes synthesized from different materials in this research are
showed in the SEM images in Figure 17 B, D, and F. The PLGA tubes have the highest
porosity, largest pore size distribution and the lowest mechanical strength. With
microspheres added into PLGA tubes, the pores are reduced in size and the strength of
the scaffold is aided by the presence of the PLLA microspheres. Similar reduced
porosity and pore size result in the increased mechanical strength occurs when PCL
microspheres are added to PLGA scaffolds. Due to the solubility of PCL is higher than
PLLA in ethyl acetate, fewer microspheres but smoother surface can be found
compared between D and F in Figure 17. The result in the compressive test also
indicates the PCL (MS)-PLGA has better mechanical strength than PLLA (MS)-PLGA.
The change of the mechanical properties of the PLGA scaffolds over time, due to
degradation, is shown in Figure 19. As the pore sizes increase and the structures get
loose over time, the mechanical properties decrease. Comparing the week-to-week
images (b, e, h,) and (c, f, i) the designed scaffolds increase their porosity and pore size
more slowly than PLGA scaffolds. Similarly, as shown in Figure 20, the mechanical
strength of the designed scaffolds decreases more slowly and the scaffold maintains its
structure longer than that of PLGA scaffolds.
4.4.3 Degradation in Mechanical Testing
During degradation, the decrease of strength stage comes earlier than loss of
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weight stage [239]. Similar tendencies have been found in degradation tests and
compressive tests. Decrease of strength and mass loss for PLGA scaffolds occur one
week earlier than for PLLA (MS)-PLGA scaffolds, and two weeks earlier than PCL
(MS)-PLGA scaffolds. Though they have similar trends, in degradation tests, the
significant mass loss begins in week 4 (when the small chains are to degrade into
monomers), while in the compressive tests the large modulus changes begin in week 1.
4.5 Compare Between Scaffolds
In this project, two types of scaffold PLLA (MS)-‐PLGA and PCL (MS)-‐PLGA are
synthesized with same process. Due to the different parameters, for example,
dissolvability and degradation speed of PLLA and PCL, two designed scaffolds
show some different characteristics in tests.
In the growth factor study, FGF-‐b is released from PLGA base to obtain the
first burst release. The PCL (MS)-‐ PLGA scaffold achieves better first release
approach with 95.43% compared with 91.65% from PLLA (MS)-‐ PLGA scaffold. In
the second release control, when EGF encapsulated in PCL microspheres initial
burst release 396.22 pg/mg, which is higher than 321.27 pg/mg released from
PLLA microspheres. This results is due to the partially dissolved PCL makes the
microspheres partially loss their function of a physical barrier. PCL degrades
slower than PLLA that makes it lowly release the encapsulated EGF from day 4 to
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day 36. Therefore, two newly designed scaffolds eventually achieve similar
sequential release profiles.
PCL has stronger initial mechanical strength and slower degradation speed
compared with PLLA. In degradation test, PCL (MS)-‐PLGA scaffold shows less mass
loss than PLLA (MS)-‐PLGA scaffold at any testing point. In mechanical test, similar
result has been found that PCL (MS)-‐ PLGA scaffold has stronger mechanical
strength and slower mechanical strength loss than PLLA (MS)-‐PLGA scaffold over
time. A followed up study shows, PLLA (MS)-‐PLGA scaffold will collapse when
applied shaking after three months, however PCL (MS)-‐ PLGA scaffold still
maintains its shape even after six months.
Both of the designed scaffolds have the similar function to sequential release
of two growth factors, however, PCL (MS)-‐PLGA scaffold has longer duration and
stronger mechanical strength compared with PLLA (MS)-‐PLGA scaffold. Therefore
PCL (MS)-‐PLGA scaffold is more capable for long-‐term regeneration study.
4.6 Conclusions
As shown above, the newly designed PLLA (MS)-PLGA scaffolds and the PCL
(MS)-PLGA scaffolds can function well as growth factors co-delivery systems. One
delivery process can be finished within a week and the other has a sustainable delivery
up to 5 to 6 weeks, which meets the demands of delivery of two different types of
105
biomolecules at different periods of spinal cord regeneration. During the synthesize
process biocompatible materials are used and no harmful solvents are used, thereby
preventing immune responses that would inhibit regeneration. By combining
microspheres made of PLLA or PCL that degrade more slowly with PLGA base
scaffolds, both the structure and the degradation rate of the scaffolds have been changed.
The resulting decrease in the pore size and the improved structure of the new scaffolds’
mechanical properties compare positively with pure PLGA scaffolds. Finally, the
extended degradation periods make the newly designed scaffolds suitable for long SCI
reparation.
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Chapter 5 Suggestions for Future Work
In this research, co-delivery scaffolds were synthesized for spinal cord injury
repairs. These improved scaffolds have a significant feature of sequential release two
molecules as well as better mechanical properties and longer duration compared with
other scaffolds. Although the new scaffolds provide better performance than the
original scaffolds, there are still some further modifications that could provide further
functional improvements.
5.1 Materials
For the co-delivery study PLLA (MS)-PLGA and PCL (MS)-PLGA scaffolds were
used to deliver two different growth factors with different release behaviors at different
periods of time, but they still have interaction during the first week. Stem cells can be
either proliferated or differentiated into determined therapeutic tissues by molecules.
Hypothetically speaking, if the system could co-deliver the two different biomolecules
at completely different times, the stem cells will get distinct signal to first proliferate,
and then later to differentiate. In this study, all the polymer materials (PLGA, PCL,
PLLA) used in the delivery systems are bulk-degradable. The diffusion rate of the
molecule is determined by character of the materials, resulting in some of the growth
factor used in second phase of regeneration being released from the microspheres in the
107
first week. If different materials are used it might be possible to prevent the release of
the second stage growth factor during the first week of reparation.
An option might be to use a different material to modify the surface of the PCL or
the PLLA microspheres. Cellulose acetate phthalate, which studied in two-dimensional
release model, has been proved with a sign to inhibit the initial release and in return to
archive sequential release of growth factors [150]. Using cellulose acetate phthalate by
coating it on the chitosan microspheres indicates the inhibit of the initial release [240].
Both of the results provide a possible clue of using it in future design to enhance the
sequential release profiles.
5.2 Microsphere Fabrication Process
Microspheres synthesized by the emulsion fabrication process as molecule-loading
system forms non-uniform molecule particles in sphere structures. In general, one
microsphere has many molecule particles distributed inside rather than one molecule
stays in the center shown in Figure 22. When doing release studies, the molecules
localized near the surface of microsphere released first [241]. If the technique could be
improved in making uniformed center molecule-loaded microspheres without damaging
the bioactivity of the molecule in shell structure, a lower initial burst of release may be
achieved. Precision particle fabrication (PPF) technology for example, by controlling
108
either speed of ejects solutions or concentration could adjust the size of the microsphere
[242] and achieve more uniform microspheres.
Figure 22 Non-ideal and ideal molecule distributions in microsphere
5.3 Micro-architecture
The micro-architecture of the newly designed scaffold can still be improved to
match spinal cord injury repair. To achieve high yield fabricated scaffolds, it is easy to
approach by modifying the scaffolds after they are synthesized. The desired scaffold
could be stuffed with another material as a core column, which can be easily shaped
into a “butterfly” to mimic the real spinal cord structure. Highly cross-linked hydrogels
have been used to bind cells with specific attachment and non-specific attachment to
cells. These cell loaded gels could be used together with the co-delivery scaffolds
developed in this thesis to achieve better functional recover after SCI.
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5.4 Inner Structure of the Scaffold
The uniform three-dimensional release of biomolecules from scaffolds is required
in various treatments. In this research, microspheres-in-tubes scaffolds were researched
to grantee a uniform release in three-dimensions. This sequential release function can
be optimized by controlling initial release of the second released molecule, for example,
by add more barrier layers to control the diffusion speed by separating microspheres
from the molecule loaded PLGA. For this idea, non-foamed and less porous material
PCL can be used as the barrier.
In Figure 23 FGF-b loaded in highly porous PLGA theoretically has the same
release kinetics as shown in this thesis. However adding the scaffold a coating material
mixed with FGF-b loaded on both the inner and outer surfaces, the FGF-b can quickly
release from both surfaces first. PCL is more resistant to CO2 diffusion in the foaming
process, creating a high density, smooth surface and slower degrading layer that works
like a barrier.
Such a design could have a more promising release profile by both accelerating the
first molecule release and delaying the second molecule release from microspheres.
This potential design has a disadvantage that, due to the non-molecule loaded PCL
barrier layers, it might be limited in the number of molecules it can deliver, when
compared to the scaffolds designed in this thesis. Since the biomolecules have an
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advantage of working in low concentration, this new possible design of scaffold could
still work for spinal cord injury repairs
Figure 23 Section view structure of improved scaffold
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Attachment
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